CN114104678A - High-strength and high-toughness die-cutting rule multilayer plane discharging device - Google Patents

Abstract

The invention relates to the technical field of die-cutting rule discharging device equipment, in particular to a high-strength and high-toughness die-cutting rule multilayer plane discharging device, which comprises: a feeding mechanism; the lifting material carrying mechanism and the material containing ring are arranged at the discharge end of the feeding mechanism, the material containing ring is arranged at the output end of the lifting material carrying mechanism and is used for bearing a die-cutting rule, the belt type conveying mechanism, the longitudinal moving mechanism and the snap ring mechanism are arranged between the feeding mechanism and the lifting material carrying mechanism, the longitudinal moving mechanism is arranged at the output end of the belt type conveying mechanism, and the snap ring mechanism is arranged at the output end of the longitudinal moving mechanism.

Description

High-strength and high-toughness die-cutting rule multilayer plane discharging device

Technical Field

The invention relates to the technical field of die-cutting rule discharging devices, in particular to a high-strength and high-toughness die-cutting rule multilayer plane discharging device.

Background

The die-cutting knife is also called a beer knife and can also be called an indentation knife; the die-cutting knife is a sheet material which is made of steel and provided with a blade at the top end, wherein the performance of the die-cutting knife requires uniform steel texture, proper hardness combination of a knife body and a knife edge, accurate specification, quenching treatment of the knife edge and the like. The hardness of the blade of the high-quality die-cutting rule is usually obviously higher than that of the cutter body, so that the die-cutting rule is convenient to form and has longer die-cutting service life;

the low peak knife is the most widely used die cutting knife, and the knife edge is small and not sharp enough. In fact, 450g/m of die-cut²The lower peak is the most desirable form for the following cardboard or some material with a thickness less than 0.5mm, and its edge support of constant thickness works well for the transfer of pressure. The smaller the cutting edge angle is, the smaller the die cutting resistance is, and the cutting edge angle is naturally sharper and easy to cut through. However, the smaller the edge angle, the more difficult it is to ensure a sharp and edge-correct broaching process. The manufacturing process of the 420-blade for grinding the cutting edge is relatively simple, but the blade performance is inferior to that of the blade manufactured by the broaching method. The 420 blade manufactured in the broaching mode has the remarkable characteristics of long service life and capability of reducing paper dust when the paperboard is die-cut;

the peak knife is designed for die cutting thick materials, and the lengthened knife edge can greatly reduce die cutting resistance and die cutting pressure and provide a good edge cutting for the thick materials;

the single-side cutter is used for die cutting of closed materials or occasions requiring straight edges; the single-sided peak knife is used for die cutting thick materials.

Because need classify the arrangement with it after the die-cutting rule processing is accomplished, but because the cutting edge of die-cutting rule is too sharp, also too dangerous through artifical the completion, so need provide a high obdurability die-cutting rule multilayer plane blowing device, can classify the die-cutting rule and put things in good order, reduced manual operation's danger, also improved work efficiency simultaneously greatly.

Disclosure of Invention

In order to solve the technical problem, the multi-layer plane material placing device of the high-strength and high-toughness die-cutting rule is provided, the die-cutting rule can be classified and stacked according to the technical scheme, the danger of manual operation is reduced, and meanwhile the working efficiency is greatly improved.

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

the utility model provides a high toughness die-cutting rule multilayer plane blowing device, includes:

a feeding mechanism;

the lifting material carrying mechanism and the material containing ring are arranged at the discharge end of the feeding mechanism, the material containing ring is arranged at the output end of the lifting material carrying mechanism, the material containing ring is used for bearing the die-cutting rule, and the lifting material carrying mechanism is used for driving the lifting material carrying mechanism to move downwards longitudinally;

the die cutting machine comprises a belt type conveying mechanism, a longitudinal moving mechanism and a clamping ring mechanism, wherein the belt type conveying mechanism, the longitudinal moving mechanism and the clamping ring mechanism are arranged between a feeding mechanism and a lifting material carrying mechanism;

the snap ring mechanism includes:

a support cylinder;

the bottom ring loading assembly is arranged at the bottom of the supporting cylinder;

the top ring loading assembly is arranged inside the supporting cylinder;

the pressing assembly is arranged at the top of the supporting cylinder, and the output end of the pressing assembly is connected with the non-working part of the top ring material loading assembly;

and the output end of the rotary driving assembly is in transmission connection with the stress ends of the bottom ring material loading assembly and the top ring material loading assembly respectively.

Preferably, the bottom of a support section of thick bamboo is provided with the backup pad, and the material subassembly is carried to the end ring includes:

the first rotating ring is arranged on the supporting plate and is rotatably connected with the supporting plate, the first rotating ring is in transmission connection with the output end of the rotating driving component, and convex columns are symmetrically arranged on the outer edge of the first rotating ring;

the stress ends of the two first connecting rods are respectively hinged with the two convex columns of the first rotating ring;

the two chamfering plugs are symmetrically arranged on the supporting cylinder and are in sliding connection with the supporting cylinder, and stress ends of the two chamfering plugs are hinged with output ends of the two first connecting rods respectively.

Preferably, the top ring loader assembly comprises:

the second rotating ring is arranged at the output end of the rotary driving component and is in transmission connection with the output end of the rotary driving component, the non-working part of the second rotating ring is connected with the output end of the pressing component, and convex columns are symmetrically arranged on the outer edge of the second rotating ring;

the stress ends of the two second connecting rods are respectively hinged with the two convex columns of the second rotating ring;

and the two flat rod plugs are symmetrically arranged on the supporting cylinder and are in sliding connection with the supporting cylinder, and the stress ends of the two flat rod plugs are respectively hinged with the output ends of the two second connecting rods.

Preferably, the compressing assembly includes:

the pressing plate is sleeved on the second rotating ring and is rotatably connected with the second rotating ring;

the first guide rod is arranged at the top of the compression plate, penetrates through the support cylinder and is in sliding connection with the support cylinder;

the first cylinder is arranged at the top of the supporting cylinder, and the output end of the first cylinder penetrates through the top fixed connection between the supporting cylinder and the pressing plate.

Preferably, the rotary drive assembly comprises:

the first servo motor is arranged at the top of the supporting cylinder;

six arris poles run through the atress end that the material subassembly was carried to the end ring and the material subassembly is carried to the apical ring to six arris poles are carried the atress end transmission of material subassembly and apical ring year material subassembly with the end ring respectively and are connected, and the top and the supporting cylinder rotatable coupling of six arris poles, the top of six arris poles and first servo motor's output transmission are connected.

Preferably, the longitudinal moving mechanism includes:

the right-angle plate is arranged at the output end of the belt type conveying mechanism;

the second cylinder is arranged at the bottom of the right-angle plate;

the push plate is arranged at the output end of the second cylinder, the bottom of the push plate is symmetrically provided with fixed rods, and the bottom of each fixed rod is fixedly connected with the top of the support cylinder;

the second guide rod is symmetrically arranged at the top of the push plate, and the top end of the second guide rod penetrates through the right-angle plate and is connected with the right-angle plate in a sliding mode.

Preferably, the belt conveyor mechanism includes:

a column frame;

the base is arranged on the upright post frame;

the first synchronizing wheel and the second synchronizing wheel are respectively arranged at two ends of the base and are rotatably connected with the base, and the first synchronizing wheel and the second synchronizing wheel are in transmission connection through a synchronous belt;

the working block is arranged on the base and is connected with the base in a sliding manner, and the stress end of the working block is connected with the output end of the synchronous belt;

and the output end of the second servo motor is connected with the stress end of the first synchronous wheel.

Preferably, lift year material mechanism includes:

lifting the material loading component;

the cylinder is arranged at the bottom of the lifting material loading assembly, the top end of the cylinder penetrates through the output end of the lifting material loading assembly, the material containing ring is sleeved on the cylinder, and the material containing ring is positioned at the output end of the lifting material loading assembly;

the material loading driving assembly is arranged at the non-working part of the lifting material loading assembly, and the output end of the material loading driving assembly is in transmission connection with the stress end of the lifting material loading assembly.

Preferably, the lifting and carrying assembly comprises:

a base plate;

the limiting rod is arranged on a triangle at the top of the bottom plate and is fixedly connected with the bottom plate;

the threaded rod is arranged at one corner of the top of the bottom plate, is rotatably connected with the bottom plate, and is connected with the output end of the loading driving assembly in a transmission manner at the bottom end;

move the board indulge, indulge to move the board and locate gag lever post and threaded rod on the cover respectively, indulge and move board and gag lever post sliding connection, indulge and move board and threaded rod threaded connection.

Preferably, the loading drive assembly comprises:

the third servo motor is arranged on the bottom plate;

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

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

Compared with the prior art, the invention has the beneficial effects that: when the die-cutting tools are processed and then fall on the output end of the feeding mechanism in sequence, the feeding mechanism starts to work, the output end of the feeding mechanism drives a plurality of die-cutting tools to convey in sequence until the die-cutting tools reach the discharge end of the feeding mechanism, when one die-cutting tool reaches the discharge end of the feeding mechanism, the feeding mechanism stops working, then the longitudinal moving mechanism starts to work, the output end of the longitudinal moving mechanism drives the clamping ring mechanism to descend until the supporting cylinder is positioned in the middle of the die-cutting tools, then the rotary driving assembly starts to work, the output end of the rotary driving assembly drives the stressed ends of the bottom ring material loading assembly and the top ring material loading assembly to rotate, the output ends of the bottom ring material loading assembly and the top ring material loading assembly simultaneously extend outwards, the output end of the bottom ring material loading assembly is positioned at the bottom of the annularly-mounted die-cutting tools, and then the output end of the top ring material loading assembly is positioned above the die-cutting tools, then the compressing component starts to work, the output end of the compressing component pushes the top ring material loading component to descend until the output end of the top ring material loading component compresses the top of the die-cutting rule, then the longitudinal moving mechanism starts to work again, the output end of the longitudinal moving mechanism pulls the snap ring mechanism to ascend, the belt type conveying mechanism starts to work, the output end of the belt type conveying mechanism drives the longitudinal moving mechanism to transversely move until the die-cutting rule moves to the top of the material containing ring, the longitudinal moving mechanism works again, the output end of the longitudinal moving mechanism drives the snap ring mechanism to descend, the snap ring mechanism works again, the compressing component works again, the output end of the compressing component drives the top ring material loading component to ascend, the rotary driving component works again, the output end of the rotary driving component drives the stressed ends of the bottom ring material loading component and the top ring material loading component to rotate, and the output ends of the bottom ring material loading component and the top ring material loading component are retracted, the die-cutting tools lose support and fall in the material containing ring, when one die-cutting tool falls in the material containing ring, the lifting material-carrying mechanism starts to work once, the output end of the lifting material-carrying mechanism drives the material containing ring to fall by the height of one die-cutting tool, and finally, a worker takes out the material containing ring, and the plurality of die-cutting tools are all positioned in the die-cutting tools;

1. the annular die-cutting rule can be quickly clamped and fixed through the arrangement of the clamping ring mechanism;

2. through the setting of this equipment, can classify and put things in good order the die-cutting sword, reduce manual operation's danger, also improve work efficiency simultaneously greatly.

Drawings

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

FIG. 2 is a front view of the present invention;

FIG. 3 is a first perspective view of the clip ring mechanism of the present invention;

FIG. 4 is a schematic perspective view of a second exemplary embodiment of a snap ring mechanism of the present invention;

FIG. 5 is a perspective view of the snap ring mechanism of the present invention in a perspective view;

FIG. 6 is a schematic perspective view of the longitudinal movement mechanism of the present invention;

FIG. 7 is a schematic perspective view of the belt conveyor of the present invention;

FIG. 8 is a first schematic perspective view of the lifting loading mechanism of the present invention;

FIG. 9 is a second schematic perspective view of the elevating loading mechanism of the present invention;

fig. 10 is an enlarged view of fig. 9 at a.

The reference numbers in the figures are:

1-a feeding mechanism;

2-a snap ring mechanism; 2 a-a support cylinder; 2a 1-support plate; 2 b-a bottom ring loading assembly; 2b1 — first rotating ring; 2b2 — first link; 2b 3-chamfered plugs; 2 c-top ring loading assembly; 2c1 — second rotating ring; 2c 2-second link; 2c 3-flat bar plug; 2 d-a hold down assembly; 2d 1-compacting plate; 2d2 — first guide bar; 2d3 — first cylinder; 2 e-a rotary drive assembly; 2e1 — first servomotor; 2e 2-hexagonal rod;

3-a longitudinal moving mechanism; 3 a-square plate; 3 b-a second cylinder; 3 c-a push plate; 3c 1-fixation bar; 3 d-a second guide bar;

4-a belt conveyor; 4 a-a post frame; 4 b-a base; 4 c-a first synchronous wheel; 4 d-a second synchronizing wheel; 4 e-a work block; 4 f-a second servo motor;

5-lifting and carrying mechanism; 5 a-lifting and carrying assembly; 5a 1-bottom plate; 5a 2-stop bar; 5a 3-threaded rod; 5a 4-longitudinal movement plate; 5 b-a cylinder; 5 c-a loading drive assembly; 5c 1-third servomotor; 5c2 — first pulley; 5c 3-second pulley;

6-material containing ring;

7-die cutting rule.

Detailed Description

The following description is presented to disclose the invention so as to enable any person skilled in the art to practice the invention. 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, 2 and 3, a high-toughness die-cutting rule multilayer plane emptying device comprises:

a feeding mechanism 1;

the lifting material loading mechanism 5 and the material containing ring 6 are arranged at the discharge end of the feeding mechanism 1, the material containing ring 6 is arranged at the output end of the lifting material loading mechanism 5, the material containing ring 6 is used for bearing the die-cutting rule, and the lifting material loading mechanism 5 is used for driving the lifting material loading mechanism 5 to move downwards longitudinally;

the device comprises a belt type conveying mechanism 4, a longitudinal moving mechanism 3 and a clamping ring mechanism 2, wherein the belt type conveying mechanism 4, the longitudinal moving mechanism 3 and the clamping ring mechanism 2 are arranged between a feeding mechanism 1 and a lifting material carrying mechanism 5, the longitudinal moving mechanism 3 is arranged at the output end of the belt type conveying mechanism 4, the clamping ring mechanism 2 is arranged at the output end of the longitudinal moving mechanism 3, the clamping ring mechanism 2 is used for clamping a die-cutting rule, the longitudinal moving mechanism 3 is used for driving the clamping ring mechanism 2 to move longitudinally, and the belt type conveying mechanism 4 is used for driving the longitudinal moving mechanism 3 to move transversely;

the snap ring mechanism 2 includes:

a support cylinder 2 a;

the bottom ring loading assembly 2b is arranged at the bottom of the supporting cylinder 2 a;

the top ring loading assembly 2c is arranged inside the supporting cylinder 2 a;

the pressing component 2d is arranged at the top of the supporting cylinder 2a, and the output end of the pressing component 2d is connected with the non-working part of the top ring loading component 2 c;

the rotary driving component 2e is arranged at the top of the supporting cylinder 2a, and the output end of the rotary driving component 2e is in transmission connection with the stress ends of the bottom ring material loading component 2b and the top ring material loading component 2c respectively;

when the die-cutting tools are processed and fall on the output end of the feeding mechanism 1 in sequence, the feeding mechanism 1 starts to work, the output end of the feeding mechanism 1 drives a plurality of die-cutting tools to convey in sequence until the die-cutting tools reach the discharge end of the feeding mechanism 1, when one die-cutting tool reaches the discharge end of the feeding mechanism 1, the feeding mechanism 1 stops working, then the longitudinal moving mechanism 3 starts to work, the output end of the longitudinal moving mechanism 3 drives the snap ring mechanism 2 to descend until the supporting cylinder 2a is positioned in the middle of the die-cutting tools, then the rotary driving component 2e starts to work, the output end of the rotary driving component 2e drives the stressed ends of the bottom ring material loading component 2b and the top ring material loading component 2c to rotate, the output ends of the bottom ring material loading component 2b and the top ring material loading component 2c extend outwards simultaneously, and the output end of the bottom ring material loading component 2b is positioned at the bottom of the ring-mounted die-cutting tools, then the output end of the top ring loading component 2c is positioned above the die-cutting rule, then the compressing component 2d starts to work, the output end of the compressing component 2d pushes the top ring loading component 2c to descend until the output end of the top ring loading component 2c compresses the top of the die-cutting rule, then the longitudinal moving mechanism 3 starts to work again, the output end of the longitudinal moving mechanism 3 pulls the snap ring mechanism 2 to ascend, the belt type conveying mechanism 4 starts to work, the output end of the belt type conveying mechanism 4 drives the longitudinal moving mechanism 3 to move transversely until the die-cutting rule moves to the top of the material containing ring 6, the longitudinal moving mechanism 3 works again, the output end of the longitudinal moving mechanism 3 drives the snap ring mechanism 2 to descend, the snap ring mechanism 2 works again, the compressing component 2d works again, the output end of the compressing component 2d drives the top ring loading component 2c to ascend, and the rotary driving component 2e works again, the output of rotary driving component 2e drives the stress end rotation of the bottom ring material loading component 2b and the top ring material loading component 2c, the output of the bottom ring material loading component 2b and the top ring material loading component 2c is withdrawn, the die-cutting rule loses the support and falls into the material containing ring 6, when one die-cutting rule falls into the material containing ring 6, the lifting material loading mechanism 5 starts to work once, the output of the lifting material loading mechanism 5 drives the material containing ring 6 to descend by the height of one die-cutting rule, finally, the worker takes out the material containing ring 6, and the multiple die-cutting rules are all positioned in the die-cutting rule.

As shown in fig. 4, the bottom of the supporting cylinder 2a is provided with a supporting plate 2a1, and the bottom ring loading assembly 2b comprises:

the first rotating ring 2b1 is arranged on the supporting plate 2a1, the first rotating ring 2b1 is rotatably connected with the supporting plate 2a1, the first rotating ring 2b1 is in transmission connection with the output end of the rotating driving component 2e, and convex columns are symmetrically arranged on the outer edge of the first rotating ring 2b 1;

the first connecting rods 2b2 and the number of the first connecting rods 2b2 is two, and the force bearing ends of the two first connecting rods 2b2 are respectively hinged with the two convex columns of the first rotating ring 2b 1;

the number of the chamfer plugs 2b3 is two, the chamfer plugs 2b3 are two, the two chamfer plugs 2b3 are symmetrically arranged on the support cylinder 2a and are in sliding connection with the support cylinder 2a, and the stressed ends of the two chamfer plugs 2b3 are respectively hinged with the output ends of the two first connecting rods 2b 2;

the output end of the rotary driving component 2e drives the first rotating ring 2b1 to rotate, the first rotating ring 2b1 drives the stressed ends of the two first connecting rods 2b2 to rotate along with the first rotating ring, the output ends of the two first connecting rods 2b2 respectively push the two chamfering plugs 2b3 to be pushed out of the supporting cylinder 2a simultaneously, the end parts of the two chamfering plugs 2b3 are chamfers and can be respectively inserted into the bottom of the die-cutting tool, the bottom of the die-cutting tool is supported by the two chamfering plugs 2b3, and the supporting plate 2a1 is used for supporting the first rotating ring 2b 1.

As shown in fig. 5, the top ring loading assembly 2c includes:

the second rotating ring 2c1 is arranged at the output end of the rotary driving component 2e, the second rotating ring 2c1 is in transmission connection with the output end of the rotary driving component 2e, the non-working part of the second rotating ring 2c1 is connected with the output end of the pressing component 2d, and convex columns are symmetrically arranged at the outer edge of the second rotating ring 2c 1;

two second connecting rods 2c2, two second connecting rods 2c2, the force bearing ends of the two second connecting rods 2c2 are hinged with the two convex columns of the second rotating ring 2c1 respectively;

two flat rod plugs 2c3, two flat rod plugs 2c3, two flat rod plugs 2c3 symmetrically arranged on the support cylinder 2a and connected with the support cylinder in a sliding manner, and the stress ends of the two flat rod plugs 2c3 are hinged with the output ends of the two second connecting rods 2c2 respectively;

the output end of the rotary driving component 2e drives the second rotating ring 2c1 to rotate, the second rotating ring 2c1 drives the stressed ends of the two second connecting rods 2c2 to rotate along with the stressed ends, the output ends of the two second connecting rods 2c2 respectively push the two flat rod plugs 2c3 to be pushed out of the supporting cylinder 2a simultaneously, the two flat rod plugs 2c3 are positioned above the annular die-cutting knife after being opened, then the pressing component 2d starts to work, and the output end of the pressing component 2d drives the top ring material loading component 2c to descend until the two flat rod plugs 2c3 press the die-cutting knife to the output end of the bottom ring material loading component 2 b.

The pressing assembly 2d shown in fig. 5 includes:

the pressing plate 2d1 is sleeved on the second rotating ring 2c1 and is rotatably connected with the second rotating ring;

the first guide rod 2d2 is arranged at the top of the pressing plate 2d1, and the first guide rod 2d2 penetrates through the supporting cylinder 2a and is connected with the supporting cylinder in a sliding way;

the first cylinder 2d3 is arranged at the top of the supporting cylinder 2a, and the output end of the first cylinder 2d3 penetrates through the supporting cylinder 2a and is fixedly connected with the top of the pressing plate 2d 1;

the pressing component 2d starts to work, the output end of the first air cylinder 2d3 pushes the pressing plate 2d1 to descend, the pressing plate 2d1 drives the top ring loading component 2c to descend until two flat rod plugs 2c3 press the top of the die-cutting knife, and the first guide rod 2d2 is used for guiding the moving direction of the pressing plate 2d 1.

The rotary drive assembly 2e shown in fig. 5 includes:

a first servo motor 2e1 provided on the top of the support cylinder 2 a;

the hexagonal rod 2e2 penetrates through the stress ends of the bottom ring material loading assembly 2b and the top ring material loading assembly 2c, the hexagonal rod 2e2 is in transmission connection with the stress ends of the bottom ring material loading assembly 2b and the top ring material loading assembly 2c respectively, the top end of the hexagonal rod 2e2 is in rotatable connection with the supporting cylinder 2a, and the top end of the hexagonal rod 2e2 is in transmission connection with the output end of the first servo motor 2e 1;

the rotary driving component 2e starts to work, the output end of the first servo motor 2e1 drives the hexagonal rod 2e2 to rotate, and the output end of the hexagonal rod 2e2 drives the force bearing ends of the bottom ring material loading component 2b and the top ring material loading component 2c to rotate.

The longitudinal moving mechanism 3 shown in fig. 6 includes:

the right-angle plate 3a is arranged at the output end of the belt type conveying mechanism 4;

the second cylinder 3b is arranged at the bottom of the right-angle plate 3 a;

the push plate 3c is arranged at the output end of the second cylinder 3b, the bottom of the push plate 3c is symmetrically provided with a fixed rod 3c1, and the bottom of the fixed rod 3c1 is fixedly connected with the top of the support cylinder 2 a;

the second guide rods 3d are symmetrically arranged at the top of the push plate 3c, and the top ends of the second guide rods 3d penetrate through the right-angle plate 3a and are in sliding connection with the right-angle plate;

the longitudinal moving mechanism 3 starts to work, the output end of the second air cylinder 3b pushes the push plate 3c to descend, the push plate 3c drives the support cylinder 2a to descend through the fixing rod 3c1, the right-angle plate 3a is used for fixed support, and the second guide rod 3d is used for guiding the moving direction of the push plate 3 c.

The belt conveyor 4 shown in fig. 7 includes:

a column frame 4 a;

a base 4b provided on the column frame 4 a;

the first synchronizing wheel 4c and the second synchronizing wheel 4d are respectively arranged at two ends of the base 4b and are rotatably connected with the base 4b, and the first synchronizing wheel 4c and the second synchronizing wheel 4d are in transmission connection through a synchronous belt;

the working block 4e is arranged on the base 4b and is in sliding connection with the base, and the stress end of the working block 4e is connected with the output end of the synchronous belt;

the second servo motor 4f is arranged on the base 4b, and the output end of the second servo motor 4f is connected with the stress end of the first synchronous wheel 4 c;

belt conveyor 4 begins work, and the output of second servo motor 4f drives first synchronizing wheel 4c and rotates, and first synchronizing wheel 4c drives the hold-in range and rotates, and the hold-in range drives work piece 4e and removes, and work piece 4e drives longitudinal movement mechanism 3 and removes to the top of flourishing material ring 6, and column frame 4a and base 4b are used for the fixed stay, and second synchronizing wheel 4d is used for supporting the hold-in range and cooperates the rotation.

As shown in fig. 8, the lifting and lowering loading mechanism 5 includes:

the material loading component 5a is lifted;

the cylinder 5b is arranged at the bottom of the lifting material loading component 5a, the top end of the cylinder 5b penetrates through the output end of the lifting material loading component 5a, the material containing ring 6 is sleeved on the cylinder 5b, and the material containing ring 6 is positioned at the output end of the lifting material loading component 5 a;

the material loading driving component 5c is arranged at the non-working part of the lifting material loading component 5a, and the output end of the material loading driving component 5c is in transmission connection with the stress end of the lifting material loading component 5 a;

when one die-cutting rule falls into the material containing ring 6, the output end of the material loading driving component 5c drives the stress end of the lifting material loading component 5a to rotate, the output end of the lifting material loading component 5a drives the material containing ring 6 to fall by the thickness of one die-cutting rule, and the cylinder 5b is used for guiding the falling direction of the die-cutting rule.

As shown in fig. 9, the elevating and lowering loader assembly 5a includes:

bottom panel 5a 1;

the limiting rod 5a2 is arranged on a triangle at the top of the bottom plate 5a1, and the limiting rod 5a2 is fixedly connected with the bottom plate 5a 1;

the threaded rod 5a3 is arranged at one corner of the top of the bottom plate 5a1, the threaded rod 5a3 is rotatably connected with the bottom plate 5a1, and the bottom end of the threaded rod 5a3 is in transmission connection with the output end of the loading driving assembly 5 c;

the longitudinal moving plate 5a4 is characterized in that the longitudinal moving plate 5a4 is respectively sleeved on the limiting rod 5a2 and the threaded rod 5a3, the longitudinal moving plate 5a4 is in sliding connection with the limiting rod 5a2, and the longitudinal moving plate 5a4 is in threaded connection with the threaded rod 5a 3;

the output end of the loading driving component 5c drives the threaded rod 5a3 to rotate, the threaded rod 5a3 drives the longitudinal moving plate 5a4 to descend by the thickness of one die-cutting rule along the limiting rod 5a2, and the bottom plate 5a1 is used for fixing and supporting.

As shown in fig. 10, the loading drive assembly 5c includes:

a third servo motor 5c1 disposed on the bottom plate 5a 1;

a first belt pulley 5c2 arranged at the output end of the third servo motor 5c 1;

the second belt pulley 5c3 is characterized in that the threaded rod 5a3 is sleeved with the second belt pulley 5c3 and fixedly connected with the second belt pulley, and the first belt pulley 5c2 is in transmission connection with the second belt pulley 5c3 through a belt;

the loading driving assembly 5c starts to work, the output end of the third servo motor 5c1 drives the first belt pulley 5c2 to rotate, the first belt pulley 5c2 drives the second belt pulley 5c3 to rotate through a belt, and the second belt pulley 5c3 drives the threaded rod 5a3 to rotate.

The working principle of the invention is as follows: when the die-cutting tools are processed and fall on the output end of the feeding mechanism 1 in sequence, the feeding mechanism 1 starts to work, the output end of the feeding mechanism 1 drives a plurality of die-cutting tools to convey in sequence until the die-cutting tools reach the discharge end of the feeding mechanism 1, when one die-cutting tool reaches the discharge end of the feeding mechanism 1, the feeding mechanism 1 stops working, then the longitudinal moving mechanism 3 starts to work, the output end of the second air cylinder 3b pushes the push plate 3c to descend, the push plate 3c drives the support cylinder 2a to descend through the fixed rod 3c1 until the support cylinder 2a is positioned in the middle of the die-cutting tools, then the rotary driving component 2e starts to work, the output end of the first servo motor 2e1 drives the hexagonal rod 2e2 to rotate, the output end of the hexagonal rod 2e2 drives the first rotary ring 2b1 and the second rotary ring 2c1 to rotate, the first rotary ring 2b1 drives the stressed ends of the two first connecting rods 2b2 to rotate along with the first connecting rod, the output ends of the two first connecting rods 2b2 push the two chamfering plugs 2b3 to be pushed out of the supporting cylinder 2a at the same time respectively, because the end parts of the two chamfering plugs 2b3 are chamfers and can be inserted into the bottom of the die-cutting tool respectively, the bottom of the die-cutting tool is supported by the two chamfering plugs 2b3, the second rotating ring 2c1 drives the stressed ends of the two second connecting rods 2c2 to rotate along with the stressed ends, the output ends of the two second connecting rods 2c2 push the two flat rod plugs 2c3 to be pushed out of the supporting cylinder 2a at the same time, the two flat rod plugs 2c3 are positioned above the annular die-cutting tool after being opened, the pressing component 2d starts to work, the output end of the first air cylinder 2d3 pushes the pressing plate 2d1 to descend, the pressing plate 2d1 drives the top ring material loading component 2c to descend until the two flat rod plugs 2c3 press the top of the die-cutting tool, the annular die-cutting tool is fixed at this time, and then the longitudinal movement mechanism 3 starts to work again, the output end of the longitudinal moving mechanism 3 pulls the snap ring mechanism 2 to ascend, the belt type conveying mechanism 4 starts to work, the output end of the second servo motor 4f drives the first synchronous wheel 4c to rotate, the first synchronous wheel 4c drives the synchronous belt to rotate, the synchronous belt drives the working block 4e to move, the working block 4e drives the longitudinal moving mechanism 3 to move to the top of the material containing ring 6, the longitudinal moving mechanism 3 works again, the output end of the longitudinal moving mechanism 3 drives the snap ring mechanism 2 to descend, the snap ring mechanism 2 works again, the pressing component 2d works again, the output end of the pressing component 2d drives the top ring material loading component 2c to ascend, the rotary driving component 2e works again, the output end of the rotary driving component 2e drives the stressed ends of the bottom ring material loading component 2b and the top ring material loading component 2c to rotate, the output ends of the bottom ring material loading component 2b and the top ring material loading component 2c to retract, the die-cutting rule loses to support and falls into containing material ring 6, when every time a die-cutting rule falls into containing material ring 6, lift year material mechanism 5 begins work, it begins work to carry material drive assembly 5c, the output of third servo motor 5c1 drives first belt pulley 5c2 and rotates, first belt pulley 5c2 drives second belt pulley 5c3 through the belt and rotates, second belt pulley 5c3 drives threaded rod 5a3 and rotates, threaded rod 5a3 drives and indulges the thickness that board 5a4 descends a die-cutting rule along gag lever post 5a2, the staff takes out containing material ring 6 at last, a plurality of die-cutting rules all are in the die-cutting rule.

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

step one, after the die-cutting rule is processed, the die-cutting rule falls on the output end of the feeding mechanism 1 in sequence;

step two, the feeding mechanism 1 starts to work, and the output end of the feeding mechanism 1 drives a plurality of die-cutting cutters to sequentially convey the die-cutting cutters until the die-cutting cutters reach the discharge end of the feeding mechanism 1;

step three, the feeding mechanism 1 starts to work, and the output end of the feeding mechanism 1 drives a plurality of die-cutting cutters to sequentially convey the die-cutting cutters until the die-cutting cutters reach the discharge end of the feeding mechanism 1;

fourthly, the rotary driving component 2e starts to work, the output end of the rotary driving component 2e drives the stress ends of the bottom ring material loading component 2b and the top ring material loading component 2c to rotate, and the output ends of the bottom ring material loading component 2b and the top ring material loading component 2c simultaneously extend outwards;

fifthly, the output end of the pressing component 2d pushes the top ring material loading component 2c to descend until the output end of the top ring material loading component 2c presses the top of the die-cutting rule tightly;

sixthly, the longitudinal moving mechanism 3 starts to work again, and the output end of the longitudinal moving mechanism 3 pulls the snap ring mechanism 2 to ascend;

seventhly, the belt type conveying mechanism 4 starts to work, and the output end of the belt type conveying mechanism 4 drives the longitudinal moving mechanism 3 to move transversely until the die-cutting rule moves to the top of the material containing ring 6;

step eight, the longitudinal moving mechanism 3 works again, and the output end of the longitudinal moving mechanism 3 drives the snap ring mechanism 2 to descend;

step nine, the snap ring mechanism 2 works again, the compression assembly 2d works again, the output end of the compression assembly 2d drives the top ring material loading assembly 2c to ascend, the rotary driving assembly 2e works again, the output end of the rotary driving assembly 2e drives the stress ends of the bottom ring material loading assembly 2b and the top ring material loading assembly 2c to rotate, and the output ends of the bottom ring material loading assembly 2b and the top ring material loading assembly 2c are retracted;

step ten, the die-cutting rule loses support and falls into the material containing ring 6;

step eleven, when one die-cutting rule falls into the material containing ring 6, the lifting material carrying mechanism 5 starts to work once, and the output end of the lifting material carrying mechanism 5 drives the material containing ring 6 to descend by the height of one die-cutting rule;

and step twelve, finally, taking out the material containing ring 6 by a worker, wherein a plurality of die-cutting cutters are all arranged in the die-cutting cutters.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. 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 invention, but that various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. The utility model provides a high obdurability die-cutting rule multilayer plane blowing device which characterized in that includes:

a feeding mechanism (1);

the lifting loading mechanism (5) and the material containing ring (6) are arranged at the discharge end of the feeding mechanism (1), the material containing ring (6) is arranged at the output end of the lifting loading mechanism (5), the material containing ring (6) is used for bearing a die-cutting rule, and the lifting loading mechanism (5) is used for driving the lifting loading mechanism (5) to longitudinally move downwards;

the device comprises a belt type conveying mechanism (4), a longitudinal moving mechanism (3) and a clamping ring mechanism (2), wherein the belt type conveying mechanism (4), the longitudinal moving mechanism (3) and the clamping ring mechanism (2) are arranged between a feeding mechanism (1) and a lifting material carrying mechanism (5), the longitudinal moving mechanism (3) is arranged at the output end of the belt type conveying mechanism (4), the clamping ring mechanism (2) is arranged at the output end of the longitudinal moving mechanism (3), the clamping ring mechanism (2) is used for clamping a die cutting knife, the longitudinal moving mechanism (3) is used for driving the clamping ring mechanism (2) to move longitudinally, and the belt type conveying mechanism (4) is used for driving the longitudinal moving mechanism (3) to move transversely;

the snap ring mechanism (2) includes:

a support cylinder (2 a);

the bottom ring loading assembly (2b) is arranged at the bottom of the supporting cylinder (2 a);

the top ring loading assembly (2c) is arranged inside the supporting cylinder (2 a);

the pressing component (2d) is arranged at the top of the supporting cylinder (2a), and the output end of the pressing component (2d) is connected with the non-working part of the top ring loading component (2 c);

and the rotary driving component (2e) is arranged at the top of the supporting cylinder (2a), and the output end of the rotary driving component (2e) is in transmission connection with the stress ends of the bottom ring material loading component (2b) and the top ring material loading component (2c) respectively.

2. The high-toughness die-cutting rule multilayer plane emptying device of claim 1, wherein the bottom of the supporting cylinder (2a) is provided with a supporting plate (2a1), and the bottom ring loading assembly (2b) comprises:

the first rotating ring (2b1) is arranged on the supporting plate (2a1), the first rotating ring (2b1) is rotatably connected with the supporting plate (2a1), the first rotating ring (2b1) is in transmission connection with the output end of the rotating driving component (2e), and convex columns are symmetrically arranged on the outer edge of the first rotating ring (2b 1);

the two first connecting rods (2b2) are provided, and the stress ends of the two first connecting rods (2b2) are respectively hinged with the two convex columns of the first rotating ring (2b 1);

the chamfering plug (2b3) comprises two chamfering plugs (2b3), the two chamfering plugs (2b3) are symmetrically arranged on the supporting cylinder (2a) and are in sliding connection with the supporting cylinder, and the stress ends of the two chamfering plugs (2b3) are hinged to the output ends of the two first connecting rods (2b2) respectively.

3. The high-toughness die-cutting rule multilayer plane emptying device of claim 1, wherein the top ring loading assembly (2c) comprises:

the second rotating ring (2c1) is arranged at the output end of the rotary driving component (2e), the second rotating ring (2c1) is in transmission connection with the output end of the rotary driving component (2e), the non-working part of the second rotating ring (2c1) is connected with the output end of the pressing component (2d), and convex columns are symmetrically arranged on the outer edge of the second rotating ring (2c 1);

two second connecting rods (2c2), wherein the number of the second connecting rods (2c2) is two, and the stress ends of the two second connecting rods (2c2) are respectively hinged with the two convex columns of the second rotating ring (2c 1);

two flat rod plugs (2c3) and two flat rod plugs (2c3), wherein the two flat rod plugs (2c3) are symmetrically arranged on the support cylinder (2a) and are in sliding connection with the support cylinder, and the stress ends of the two flat rod plugs (2c3) are respectively hinged with the output ends of the two second connecting rods (2c 2).

4. The high-toughness die-cutting rule multilayer plane emptying device of claim 3, wherein the compressing assembly (2d) comprises:

the pressing plate (2d1) is sleeved on the second rotating ring (2c1) and is rotatably connected with the second rotating ring;

the first guide rod (2d2) is arranged at the top of the pressing plate (2d1), and the first guide rod (2d2) penetrates through the supporting cylinder (2a) and is connected with the supporting cylinder in a sliding way;

the first cylinder (2d3) is arranged at the top of the supporting cylinder (2a), and the output end of the first cylinder (2d3) penetrates through the supporting cylinder (2a) and is fixedly connected with the top of the pressing plate (2d 1).

5. The high-toughness die-cutting rule multilayer plane emptying device of claim 1, wherein the rotary driving assembly (2e) comprises:

a first servo motor (2e1) arranged on the top of the support cylinder (2 a);

hexagonal pole (2e2), the atress end that the material subassembly (2c) was carried to the bottom ring of running through and the top ring to hexagonal pole (2e2) carry the atress end transmission of material subassembly (2b) and top ring year material subassembly (2c) with the bottom ring respectively and are connected, the top and the support cylinder (2a) rotatable coupling of hexagonal pole (2e2), the top of hexagonal pole (2e2) is connected with the output transmission of first servo motor (2e 1).

6. The high-toughness die-cutting rule multilayer plane emptying device as claimed in claim 1, wherein the longitudinal moving mechanism (3) comprises:

the right-angle plate (3a) is arranged at the output end of the belt type conveying mechanism (4);

the second cylinder (3b) is arranged at the bottom of the right-angle plate (3 a);

the push plate (3c) is arranged at the output end of the second cylinder (3b), fixing rods (3c1) are symmetrically arranged at the bottom of the push plate (3c), and the bottom of each fixing rod (3c1) is fixedly connected with the top of the support cylinder (2 a);

and the second guide rods (3d) are symmetrically arranged at the top of the push plate (3c), and the top ends of the second guide rods (3d) penetrate through the right-angle plate (3a) and are in sliding connection with the right-angle plate.

7. The high-toughness die-cutting rule multilayer plane emptying device of claim 1, wherein the belt type conveying mechanism (4) comprises:

a column frame (4 a);

a base (4b) provided on the column frame (4 a);

the first synchronizing wheel (4c) and the second synchronizing wheel (4d) are respectively arranged at two ends of the base (4b) and rotatably connected with the base, and the first synchronizing wheel (4c) and the second synchronizing wheel (4d) are in transmission connection through a synchronous belt;

the working block (4e) is arranged on the base (4b) and is in sliding connection with the base, and the stress end of the working block (4e) is connected with the output end of the synchronous belt;

and the second servo motor (4f) is arranged on the base (4b), and the output end of the second servo motor (4f) is connected with the stress end of the first synchronous wheel (4 c).

8. The high-toughness die-cutting rule multilayer plane emptying device as claimed in claim 1, wherein the lifting loading mechanism (5) comprises:

a lifting loading component (5 a);

the cylinder (5b) is arranged at the bottom of the lifting material carrying assembly (5a), the top end of the cylinder (5b) penetrates through the output end of the lifting material carrying assembly (5a), the material containing ring (6) is sleeved on the cylinder (5b), and the material containing ring (6) is positioned at the output end of the lifting material carrying assembly (5 a);

the material loading driving component (5c) is arranged at the non-working part of the lifting material loading component (5a), and the output end of the material loading driving component (5c) is in transmission connection with the stress end of the lifting material loading component (5 a).

9. The high-toughness die-cutting rule multilayer plane emptying device of claim 8, wherein the lifting loading assembly (5a) comprises:

a bottom panel (5a 1);

the limiting rod (5a2) is arranged on a triangle at the top of the bottom plate (5a1), and the limiting rod (5a2) is fixedly connected with the bottom plate (5a 1);

the threaded rod (5a3) is arranged at one corner of the top of the bottom plate (5a1), the threaded rod (5a3) is rotatably connected with the bottom plate (5a1), and the bottom end of the threaded rod (5a3) is in transmission connection with the output end of the loading driving component (5 c);

the vertical moving plate (5a4), the vertical moving plate (5a4) is respectively sleeved on the limiting rod (5a2) and the threaded rod (5a3), the vertical moving plate (5a4) is connected with the limiting rod (5a2) in a sliding mode, and the vertical moving plate (5a4) is connected with the threaded rod (5a3) in a threaded mode.

10. The high-toughness die-cutting rule multilayer plane emptying device of claim 9, wherein the loading driving component (5c) comprises:

a third servo motor (5c1) arranged on the bottom plate (5a 1);

a first belt pulley (5c2) arranged at the output end of the third servo motor (5c 1);

the second belt pulley (5c3), second belt pulley (5c3) cover are located threaded rod (5a3) and are connected with it fixed connection, pass through belt drive between first belt pulley (5c2) and the second belt pulley (5c 3).

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