CN207172646U

CN207172646U - A kind of material head blanking units of knife-fork-spoon

Info

Publication number: CN207172646U
Application number: CN201721079996.5U
Authority: CN
Inventors: 王兴东
Original assignee: ACMEPLAS SYSTEM TECHNOLOGIES Ltd
Current assignee: ACMEPLAS SYSTEM TECHNOLOGIES Ltd
Priority date: 2017-08-25
Filing date: 2017-08-25
Publication date: 2018-04-03
Anticipated expiration: 2027-08-25

Abstract

The utility model discloses a kind of material head blanking units of knife-fork-spoon, including punching workbench, slug head moving mechanism and slug head.Four pieces of product templates are uniformly installed in punching work；To privately setting two scheduling product die cavities and opening up a charging conduit between two scheduling product die cavities in every piece of product template, every charging conduit relatively opens up through hole on the punching workbench；Slug head moving mechanism includes Y-axis moving mechanism and Z axis travel mechanism；Y-axis moving mechanism includes Y-axis girder, master and slave synchronous pulley, timing belt, y-axis motor and Y-axis moving plate；The Z axis travel mechanism includes Z axis girder, Z axis motor, ball wire rod mechanism and Z axis movable plate；Slug head includes a point of air parcel, a punching plate, four stamping cylinders, four pressing blocks, eight row pressure material tools and eight groups of air blowing plates.Material head blanking units of the present utility model, automatic slug and the finished product transport of product are realized, defect rate can be reduced, and can improves production efficiency.

Description

Stub bar punching device of knife, fork and spoon

Technical Field

The utility model relates to an injection moulding packaging system of knife and fork spoon, concretely relates to die-cut device of stub bar of knife and fork spoon.

Background

The knife, fork and spoon injection molding piece is formed by an injection molding machine. The knife, fork and spoon products produced by the injection molding machine are not final products, and the injection molding parts are required to be subjected to subsequent processing treatment to be packaged and delivered out of a factory. The traditional method of disposal is by manual cutting of unwanted injection molding waste, leaving behind the desired injection molded product. Although the injection molding improves the production efficiency, the manual processing at the later stage occupies a large amount of time, the whole production efficiency is reduced, and the size and the shape of the manually processed product are often not accurate enough, so that the defective rate is increased.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome prior art's defect and provide a die-cut device of stub bar of fork spoon, it has realized that the automation of product is towards material and finished product transportation, can not only reduce the defective percentage, can also improve production efficiency.

The purpose of the utility model is realized like this: a stub bar punching device of a knife-fork spoon is arranged in a punching rack on the left side of an injection molding packaging system of the knife-fork spoon and comprises a punching workbench, a punching stub bar moving mechanism and a punching stub bar;

four product templates are uniformly distributed and installed on the punching work; two rows of product cavities are arranged on each product template in a back-to-back manner, a charging chute is arranged between the two rows of product cavities, and a through hole is formed in the punching workbench relative to each charging chute;

the blanking head moving mechanism comprises a Y-axis moving mechanism and a Z-axis moving mechanism; wherein,

the Y-axis moving mechanism comprises a Y-axis main beam, a main synchronous belt wheel, a secondary synchronous belt wheel, a synchronous belt, a Y-axis motor and a Y-axis moving plate; the Y-axis main beam is a C-shaped component with an opening at the lower end, is arranged on a top middle longitudinal beam of the punching rack and is positioned at the rear upper part of the punching workbench; the main synchronous pulleys and the auxiliary synchronous pulleys are arranged at the rear end and the front end of the Y-axis main beam in a one-to-one correspondence manner; the synchronous belt is wrapped on the primary synchronous belt wheel and the secondary synchronous belt wheel; the Y-axis motor is connected to the main synchronous belt wheel; the Y-axis moving plate is arranged on the synchronous belt through a synchronous belt pressing block and a synchronous belt pressing plate and is positioned on the lower end face of the Y-axis main beam;

the Z-axis moving mechanism comprises a Z-axis main beam, a Z-axis motor, a ball screw mechanism and a Z-axis moving plate; the Z-axis main beam is a frame body of a Z-axis housing with an opening at the rear end; the Z-axis motor is arranged on the top surface of the Z-axis main beam; the ball screw mechanism is arranged in the Z-axis main beam and is connected with the Z-axis motor; the Z-axis moving plate is connected to a nut seat of the ball screw mechanism and is connected with the Y-axis moving plate through a top plate;

the punching head comprises an air distribution block, a punching plate, four punching cylinders, four punching blocks, eight rows of pressing jigs and eight groups of air blowing plates; the air distribution block is connected to the lower end of the Z-axis main beam; the punching plate is matched with the table top of the punching workbench in shape and is arranged on the lower end face of the gas distribution block; the four stamping cylinders correspond to the centers of the charging chutes of the four product templates one by one and are arranged on the upper end surface of the stamping plate in a mode that piston rods of the stamping cylinders downwards penetrate through the stamping plate; the shape of the stamping blocks is matched with that of the charging chute, and the four stamping blocks are arranged below the stamping and cutting plate and are connected to the lower ends of the piston rods of the four stamping cylinders in a one-to-one correspondence manner; eight rows of pressing jigs are arranged on the lower end surface of the punching plate, and the eight rows of pressing jigs are in one-to-one correspondence and are positioned on the left side and the right side of the four punching blocks in a close distance; eight groups of air blowing plates are arranged on the lower end surface of the punching plate, and the eight groups of air blowing plates are correspondingly arranged on the left side and the right side of the four punching blocks in a long distance; each group of air blowing plates consists of two air blowing plates arranged in parallel, one end of each air blowing plate is communicated with the air distribution block, and a row of suckers are arranged on the lower end face of each air blowing plate.

The four product templates comprise two fork templates, a spoon template and a knife template.

The blanking device of the stub bar of the knife, fork and spoon is characterized in that the Y-axis moving mechanism further comprises a Y-axis protection mechanism, and the Y-axis protection mechanism comprises a Y-axis origin sensor, a Y-axis limit sensor and a Y-axis induction sheet, wherein the Y-axis origin sensor and the Y-axis limit sensor are arranged in front of and at the rear of the outer wall of the Y-axis main beam in a one-to-one correspondence manner, and the Y-axis induction sheet is arranged on the synchronous.

The blanking device of the stub bar of the knife, fork and spoon is characterized in that a pair of Y-axis slide rails is installed on the lower end face of the Y-axis main beam, and a pair of Y-axis slide grooves matched with the pair of Y-axis slide rails one by one are installed on the upper end face of the Y-axis movable plate.

The blanking device for the stub bar of the knife-fork spoon comprises a Z-axis moving mechanism, wherein the Z-axis moving mechanism further comprises two vertical limiting grooves formed in a Z-axis moving plate, a pair of anti-collision blocks installed on the top surface of a Z-axis main beam and inserted into the two limiting grooves in a one-to-one correspondence mode, an origin inductor and a limit inductor which are installed on the side surface of the Z-axis moving plate one by one, and a Z-axis induction sheet installed on a Z-axis cover shell.

The blanking device for the stub bar of the knife-fork spoon is characterized in that a pair of Z-axis slide rails is mounted on the rear end face of the Z-axis main beam, and a pair of Z-axis slide grooves matched with the pair of Z-axis slide rails one by one are mounted on the front end face of the Z-axis movable plate.

The blanking head of the knife-fork spoon further comprises four pairs of guide columns which are respectively arranged on the blanking plate through linear bearings and are respectively positioned on two sides of the four stamping cylinders, and the lower ends of each pair of guide columns are respectively connected with two ends of the stamping block.

The material head punching device of the knife-fork spoon comprises four pairs of reinforcing ribs, wherein the four pairs of reinforcing ribs are fixed on the upper end face of the punching plate and located on two sides of the air distribution block.

The material head punching device of the knife, fork and spoon comprises four speed regulating valves respectively arranged on four punching cylinders.

The stub bar crushing machine is further mounted below the punching workbench and comprises a material receiving funnel fixed on the lower end face of the punching workbench, a crushing box connected to the lower end of the material receiving funnel, a material suction machine mounted at a discharge port of the crushing box and a waste recovery pipe connected between the material suction machine and an injection molding machine.

The utility model discloses a die-cut device of stub bar of fork spoon has following characteristics: the servo motor is adopted to control the material punching head to move back and forth and move up and down, so that the waste material head can be accurately punched for a product injection molding piece placed on a punching workbench, then a finished product with the waste material head cut off can be accurately conveyed to a subsequent station, the defective rate of injection molding products can be reduced to the greatest extent, the labor intensity is reduced, the safety of operators is improved, the production period can be shortened, and the production efficiency is improved.

Drawings

Fig. 1 is a schematic view of the installation position of the stub bar punching device of the knife and fork spoon of the present invention;

FIG. 2 is a right side isometric view of a stub bar die cutting apparatus of the knife and fork spoon of the present invention;

fig. 3 is a top isometric view of a die cutting table in the slug die cutting apparatus of the knife and fork scoop of the present invention;

fig. 4a is an exploded perspective view of a Y-axis moving mechanism in a stub bar punching device of a knife and fork scoop according to the present invention;

fig. 4b is a bottom perspective view of the Y-axis moving mechanism in the stub bar punching device of the knife and fork scoop of the present invention;

fig. 5a is an exploded perspective view of a Z-axis moving mechanism in a stub bar punching device of a knife and fork scoop according to the present invention;

fig. 5b is a front isometric view of the Z-axis moving mechanism in the bit blanking apparatus of the knife and fork scoop of the present invention;

fig. 6a is a top isometric view of a blanking head in a blanking device for a cutlery spoon of the present invention;

fig. 6b is a bottom perspective view of the blanking head of the blanking device of the knife and fork scoop of the present invention.

Detailed Description

The present invention will be further explained with reference to the accompanying drawings.

Referring to fig. 1 to 6b, the material head punching device of the knife, fork and spoon of the present invention is installed in the left punching frame 100 of the injection molding and packaging system of the knife, fork and spoon and includes a punching worktable 10, a material head moving mechanism and a material head 40.

Four product templates are uniformly arranged on the punching workbench 10; wherein, two rows of product cavities 14 are arranged on each product template in a back-to-back manner, and a charging chute 15 is arranged between the two rows of product cavities 14; through holes are formed in the punching workbench 10 corresponding to each charging chute 15; the four product templates comprise two fork templates 11 which are arranged at the front part of the punching workbench 10 from left to right, a spoon template 12 which is arranged at the rear part of the punching workbench 10 from left to right and a knife template 13; the number of product cavities 14 in each row is eight. A stub bar crusher 16 is further installed under the punching worktable 10, and includes a receiving hopper 161 fixed on the lower end surface of the punching worktable 10, a crushing box 162 connected to the lower end of the receiving hopper 161, a suction machine 163 installed at the discharge port of the crushing box 162, and a scrap recycling pipe (not shown) connected between the suction machine 163 and the injection molding machine.

The blanking head moving mechanism includes a Y-axis moving mechanism 20 and a Z-axis moving mechanism 30.

The Y-axis moving mechanism 20 includes a Y-axis main beam 21, a master and slave timing pulleys 22, 22', a timing belt 23, a Y-axis motor 24, a Y-axis moving plate 25 and a Y-axis protection mechanism, wherein:

the Y-axis main beam 21 is a C-shaped component with an opening at the lower end, and the Y-axis main beam 21 is installed on a top middle longitudinal beam of the punching rack 100 and is positioned at the rear upper part of the punching workbench 10; a pair of Y-axis slide rails 26 are arranged on the lower end surface of the Y-axis main beam 21; a cover 28 is also arranged at the rear end of the Y-axis main beam 21, and a drag chain 29 is also connected to the cover 28;

the main and auxiliary synchronous pulleys 22, 22' are mounted at the rear end and the front end of the Y-axis main beam 21 in a one-to-one correspondence manner;

the synchronous belt 23 is wound on the primary and secondary synchronous pulleys 22 and 22';

the Y-axis motor 24 is connected to the main synchronous belt pulley 22 through a speed reducer 240;

the Y-axis moving plate 25 is arranged on the synchronous belt 23 through a synchronous belt pressing block 231 and a synchronous belt pressing plate 232 and is positioned on the lower end face of the Y-axis main beam 21; a pair of Y-axis sliding grooves 27 matched with the pair of Y-axis sliding rails 26 one by one are arranged on the upper end surface of the Y-axis moving plate 25;

the Y-axis protection mechanism includes Y-axis origin sensors 281 and Y-axis limit sensors 282 installed at the front and rear portions of the outer wall of the Y-axis main beam 21 in a one-to-one correspondence, and Y-axis sensing pieces 283 installed on the timing belt press block 241.

The Z-axis moving mechanism 30 comprises a Z-axis main beam 31, a Z-axis motor 32, a ball screw mechanism 33, a Z-axis moving plate 34 and a Z-axis protection mechanism; wherein:

the Z-axis main beam 31 is a frame body of the Z-axis housing 310 with an opening at the rear end; a pair of Z-axis slide rails 36 are arranged on the rear end surface of the Z-axis main beam 31;

the Z-axis motor 32 is arranged on the top surface of the Z-axis main beam 31;

the ball screw mechanism 33 is arranged in the Z-axis main beam 31 and is connected with the Z-axis motor 32 through a coupling 320;

a Z-axis moving plate 34 is connected to a nut holder 330 of the ball screw mechanism 33, and the Z-axis moving plate 34 is connected to the Y-axis moving plate 25 through a top plate 35; a supporting rib plate 340 is respectively connected between two sides of the lower end surface of the top plate 35 and the rear end surface of the Z-axis moving plate 34;

a pair of Z-axis sliding grooves 37 which are matched with the pair of Z-axis sliding rails 36 one by one are arranged on the front end surface of the Z-axis moving plate 34;

the Z-axis protection mechanism includes two vertical limit grooves 381 formed on the Z-axis moving plate 34, a pair of anti-collision blocks 382 installed on the top surface of the Z-axis main beam 31 and inserted into the two limit grooves 381 in a one-to-one correspondence manner, an origin sensor 391 and a limit sensor 392 installed on the side surface of the Z-axis moving plate 34 one above the other, and a Z-axis sensing piece 393 installed on the Z-axis housing 310.

The punching head 40 comprises an air distribution block 41, a punching plate 42, eight reinforcing ribs 43, four punching cylinders 44, four pairs of guide columns 45, four punching blocks 46, eight rows of pressing jigs 47 and eight groups of air blowing plates 48; wherein:

the air distribution block 41 is connected to the lower end of the Z-axis main beam 31;

the punching plate 42 is matched with the table top shape of the punching workbench 10 and is arranged on the lower end face of the gas distribution block 41;

eight reinforcing ribs 43 are fixed on the upper end surface of the die-cutting plate 42 and are positioned on two sides of the gas distribution block 41 at intervals in pairs;

the four stamping cylinders 44 correspond to the centers of the charging chutes 15 of the four product templates one by one and are arranged on the upper end surfaces of the stamping plates 42 in a manner that piston rods of the stamping cylinders downwards penetrate through the stamping plates 42; the four stamping cylinders 44 are respectively provided with a speed regulating valve 440;

the four pairs of guide posts 45 are respectively installed on the punching plate 42 through linear bearings 450 and are respectively positioned at two sides of the four punching cylinders 44;

the shape of the punching block 46 is matched with that of the charging chute 15, the four punching blocks 46 are arranged below the punching plate 42 and are connected to the lower ends of the piston rods of the four punching cylinders 44 in a one-to-one correspondence manner, and two ends of each punching block 46 are also connected with the lower ends of the pair of guide columns 45 respectively;

eight rows of pressing jigs 47 are all installed on the lower end face of the die-cutting plate 42, and the eight rows of pressing jigs 47 are located on the left side and the right side of the four punching blocks 46 in a one-to-one correspondence and in a close distance; the number of each row of the pressing jigs 47 is the same as that of the product cavities 14 in the row;

eight groups of air blowing plates 48 are all arranged on the lower end face of the punching plate 42, and the eight groups of air blowing plates 48 are correspondingly arranged on the left side and the right side of the four punching blocks 46 in a one-to-one mode and are far away; each group of air blowing plates 48 consists of two air blowing plates 48 which are arranged in parallel, one end of each air blowing plate 48 is communicated with the air distribution block 41, and the lower end face of each air blowing plate 48 is provided with a row of suckers 49 through hardware fittings; the number of suction cups 49 in a row is the same as the number of product cavities 14 in a row.

The utility model discloses a die-cut device of stub bar of knife and fork spoon's working process is:

firstly, a product injection molding piece taken out from an injection molding machine is accurately sent into a product cavity 14 of a product template on a punching worktable 10 by a side taking device of an injection molding packaging system of a knife fork spoon, then a synchronous belt 23 moves under the driving of a Y-axis motor 24, a Y-axis moving plate 25 arranged on the synchronous belt 23 moves, a Z-axis main beam 31 is driven to move from the rear part to the front end of the Y-axis main beam 21 by the Z-axis moving plate 34 connected with the Y-axis moving plate 25, a punching head 40 arranged at the lower end of the Y-axis main beam 21 moves to the right upper part of the punching worktable 10, a ball screw mechanism 33 moves under the driving of the Z-axis motor 32, so that the Z-axis main beam 31 connected to a nut seat 330 of the ball screw mechanism 33 is driven to move downwards, an eight-row material pressing jig 47 on the punching head 40 presses the handle part of the product injection molding piece in the product template for positioning, and a piston rod of a, the punching block 46 is driven to move downwards to cut off the stub bars between the tail ends of two rows of product injection molding pieces on each product template, then the suction cups 49 on eight groups of air blowing plates 48 suck the finished products with the stub bars cut off, the blanking heads 40 which suck the finished products are driven to move upwards by the Z-axis motor 32 and move to the rear part of the Y-axis main beam 21 under the drive of the Y-axis motor 24 to reach the subsequent station, namely above the stacking and transferring device, finally the blanking heads 40 which suck the finished products are driven to move downwards by the Z-axis motor 32, the finished products are released by the suction cups 49, and the finished products are stacked in the stacking jig in the stacking and transferring device. The formed product is firmly fixed on the sucking disc due to the suction force in the conveying process, and cannot be subjected to other acting force or contact surface deviation between the sucking disc and the formed product, so that the formed product is deformed in the conveying process, the formed product conveyed at the next time is adjusted through the Z-axis moving mechanism 30, and is directly placed on the formed product conveyed at the previous time, and the direct placing and stacking mode is adopted. In addition, the number of the suckers on the air blowing plate 48 is fixed, the total stacking number of the formed products can be obtained through the carrying times, the statistics of a producer is facilitated, and meanwhile, the number of the suckers on the suction device can be adjusted according to production requirements.

After the product stub bar is punched, when falling into the crushing box 162 through the blanking groove 15 on the product template and the through hole on the punching workbench 10 and through the receiving hopper 161, crushing is carried out through the crushing knife in the crushing box 162, and the crushed material powder is recycled into the material barrel of the injection molding machine through the suction machine 163 for reuse. The speed regulating valve 440 on the punching cylinder 44 can regulate the air flow of the punching cylinder 44, thereby controlling the speed of the piston rod of the punching cylinder 44. Each pair of guide posts 45 cooperates with the punch cylinder 44 to guide the punching action of each punch block 46.

The above embodiments are provided only for the purpose of illustration, not for the limitation of the present invention, and those skilled in the relevant art can make various changes or modifications without departing from the spirit and scope of the present invention, therefore, all equivalent technical solutions should also belong to the scope of the present invention, and should be defined by the claims.

Claims

1. A stub bar punching device of a knife-fork spoon is arranged in a punching frame on the left side of an injection molding packaging system of the knife-fork spoon and comprises a punching workbench, a punching stub bar moving mechanism and a punching stub bar,

2. The apparatus of claim 1 wherein the four product templates include two fork templates, a scoop template, and a knife template.

3. The apparatus of claim 1, wherein the Y-axis moving mechanism further comprises a Y-axis protection mechanism, the Y-axis protection mechanism comprises a Y-axis origin sensor and a Y-axis limit sensor mounted in front of and behind the outer wall of the Y-axis main beam in a one-to-one correspondence, and a Y-axis sensing piece mounted on the timing belt pressing block.

4. The stub bar punching device of a knife, fork and spoon according to claim 1 or 3, characterized in that a pair of Y-axis slide rails is installed on the lower end face of the Y-axis main beam, and a pair of Y-axis slide grooves matched with the pair of Y-axis slide rails one by one is installed on the upper end face of the Y-axis moving plate.

5. The apparatus of claim 1, wherein the Z-axis moving mechanism further comprises a Z-axis protection mechanism, the Z-axis protection mechanism comprises two vertical limiting grooves formed on the Z-axis moving plate, a pair of anti-collision blocks mounted on the top surface of the Z-axis main beam and inserted into the two limiting grooves in a one-to-one correspondence manner, an origin sensor and a limit sensor mounted on the side surface of the Z-axis moving plate one above the other, and a Z-axis sensing piece mounted on the Z-axis housing.

6. The stub bar die-cutting device of a knife, fork and spoon according to claim 1 or 5, characterized in that a pair of Z-axis slide rails is installed on the rear end face of the Z-axis main beam, and a pair of Z-axis chutes that are one-to-one adapted to the pair of Z-axis slide rails is installed on the front end face of the Z-axis moving plate.

7. The apparatus of claim 1, wherein the blanking head further comprises four pairs of guide posts each mounted on the blanking plate via a linear bearing and located on either side of each of the four stamping cylinders, and the lower ends of each pair of guide posts are connected to the two ends of the stamping block.

8. The stub bar die-cutting device of claim 1, wherein the stub bar further comprises four pairs of reinforcing ribs fixed to the upper end surface of the die-cutting plate and located on two sides of the air distribution block.

9. The apparatus of claim 1 wherein the blanking head further comprises four speed valves mounted on four respective ram cylinders.

10. The stub bar punching device of a knife-fork scoop according to claim 1, characterized in that a stub bar crusher is further installed below the punching workbench, and the stub bar crusher comprises a material receiving funnel fixed on the lower end surface of the punching workbench, a crushing box connected to the lower end of the material receiving funnel, a material suction machine installed at the discharge port of the crushing box, and a waste recovery pipe connected between the material suction machine and an injection molding machine.