CN213858214U - Automatic milling tool for injection molding parts - Google Patents

Abstract

The utility model provides an injection molding automatic milling frock, solves that many pairs of moulds that prior art exists process the cost height, and it is difficult to guarantee to produce the finished product quality, and intensity of labour is big, production efficiency is low, occupies limited production space, the poor problem of practicality. Be provided with the fetal membrane base of middle part fetal membrane including the middle part, its characterized in that: two sides of the waste discharge port in the middle of the middle fetal membrane are respectively provided with a middle positioning groove; front side limiting struts are respectively arranged in front of the side part membranes at two sides of the middle membrane and at one side close to the middle membrane, and a front side supporting block is arranged in front of the middle membrane; and rotary air cylinders are respectively arranged on two sides of a rear side limiting support arranged behind the middle tire membrane, and rotary pressing blocks are respectively arranged at the rotary ends of the rotary air cylinders. Its reasonable in design, compact structure is convenient for carry out the processing of automatic milling pore-forming to the grid body of moulding plastics, has effectively reduced artifical intensity of labour and the latency of changing the mould, guarantees the finished product quality, practices thrift manufacturing cost, and the practicality is strong.

Description

Automatic milling tool for injection molding parts

Technical Field

The utility model belongs to the technical field of the automated production, concretely relates to be convenient for carry out the processing of automatic milling pore-forming to the grid body of moulding plastics, effectively reduce artifical intensity of labour and the latency of changing the mould, can guarantee the product quality, practice thrift manufacturing cost, the injection molding automatic milling frock that the practicality is strong.

Background

The same type product of the existing automobile injection molding grating can have a plurality of styles, and a pair of molds is separately equipped when the injection molding grating of each style is manufactured, and a production mode of mold injection molding is adopted. However, the traditional production mode has the disadvantages of high processing cost of the die, difficulty in ensuring the quality of the finished product, high labor intensity and low production efficiency; in addition, the idle molds occupy a large amount of limited production space of a factory, and the practicability is poor. Therefore, the structure of the injection grid pore-forming die in the prior art needs to be improved.

SUMMERY OF THE UTILITY MODEL

The utility model is exactly to above-mentioned problem, provide a be convenient for carry out the processing of automatic milling pore-forming to the grid body of moulding plastics, effectively reduce artifical intensity of labour and the latency of changing the mould, can guarantee to produce the product quality, practice thrift manufacturing cost, the injection molding automatic milling frock that the practicality is strong.

The utility model adopts the technical proposal that: this injection molding automatic milling frock includes the fetal membrane base, its characterized in that: the middle part of the upper side of the fetal membrane base is provided with a middle fetal membrane, the middle fetal membrane is composed of a middle fetal membrane main body, the middle part of the middle fetal membrane main body is provided with a waste discharge port, two sides of the waste discharge port and the upper part of the middle fetal membrane main body are respectively provided with a plurality of groups of middle positioning grooves, and the middle fetal membrane main body is detachably connected with the upper side of the fetal membrane base through middle fetal membrane connecting tables at two sides; the left side and the right side of the middle fetal membrane are respectively provided with a side fetal membrane, the front sides of the side fetal membranes at the two sides and one side close to the middle fetal membrane are respectively provided with a front side limiting strut, and the two sides of the front side of the middle fetal membrane are respectively provided with a front side supporting block; meanwhile, two groups of middle supporting blocks are further arranged in the waste discharging port of the middle tire membrane, a rear side limiting strut is arranged behind the middle tire membrane, rotary cylinders which are vertically arranged are respectively arranged on two sides of the rear side limiting strut, and each rotary cylinder is located at the rotary end above the middle tire membrane and is respectively provided with a rotary pressing block.

The side tire membrane is composed of a side tire membrane main body, a plurality of groups of side positioning grooves are arranged on the side tire membrane main body, and the side tire membrane main body is detachably connected with the upper side of the tire membrane base through a side tire membrane connecting table on the side. The injection molding piece to be milled is stably placed on the middle tire membrane and the side tire membranes on the two sides by utilizing the side positioning grooves on the side tire membranes and the middle positioning groove on the middle tire membrane; and the use flexibility of the tool is increased through the detachable side part tire membranes and the detachable middle part tire membranes.

The front side limiting strut is composed of a front strut main body which is vertically arranged, and a front side limiting clamping groove is formed in one side, facing the lateral fetal membrane, of the front strut main body; and the front strut main body is detachably connected with the upper side of the fetal membrane base through a front strut connecting part at the lower end. The front side limiting support column is arranged at one side, close to the middle tire membrane, in front of the side tire membrane and used for clamping and limiting two end parts of the front side of the injection molding part to be milled, which is placed on the middle tire membrane and the side tire membrane.

The front side supporting block is composed of a cuboid front supporting block main body, and the lower portion of the front supporting block main body is detachably connected with the upper side of the fetal membrane base through a front supporting block connecting portion. So as to utilize the front side supporting block arranged in front of the middle tire membrane to support the lower part of the front side of the injection molding piece placed on the middle tire membrane and the side tire membrane.

The middle supporting block arranged in the waste discharge port of the middle tire membrane is composed of a middle supporting block main body, and the middle supporting block main body is detachably connected with the upper side of the tire membrane base through a middle supporting block connecting part. In order to utilize the middle part supporting shoe that sets up in the waste discharge port, support the downside in the middle part of placing the injection molding on middle part fetal membrane.

The rear side limiting strut is composed of a rear strut main body, a rear side limiting clamping groove is formed in one side, facing the middle fetal membrane, of the rear strut main body, and the lower end of the rear strut main body is detachably connected with the upper side of the fetal membrane base through a rear strut connecting portion. The rear side limiting strut is arranged behind the middle tire membrane and used for clamping and limiting the rear side of the injection molding piece to be milled, which is placed on the middle tire membrane.

The rotary pressing block arranged on the rotary end of the rotary cylinder is composed of a pressing block main body, one end of the pressing block main body is fixedly connected with the rotary end of the rotary cylinder through a rotary cylinder connecting portion, and a workpiece pressing portion is arranged on the lower side of the other end of the pressing block main body. The rotating pressing block is driven to rotate to lift in a reciprocating manner through the rotating cylinder, and then the injection molding part to be milled is clamped and pressed by the workpiece pressing and fixing part at the end part of the rotating pressing block.

And base handles are respectively arranged at two ends of the fetal membrane base. The whole milling tool is convenient to mount and dismount on a working panel of machining equipment.

The utility model has the advantages that: because the utility model adopts the fetal membrane base with the middle fetal membrane arranged in the middle, the middle part of the middle fetal membrane main body of the middle fetal membrane is provided with the waste discharge port, a plurality of groups of middle positioning grooves are respectively arranged on the middle fetal membrane main body and on the two sides of the waste discharge port, and the middle fetal membrane main body is detachably connected with the upper side of the fetal membrane base through the middle fetal membrane connecting tables on the two sides; the left side and the right side of the middle fetal membrane are respectively provided with a side fetal membrane, the front sides of the side fetal membranes at the two sides and one side close to the middle fetal membrane are respectively provided with a front side limiting strut, and the two sides of the front side of the middle fetal membrane are respectively provided with a front side supporting block; the waste material discharge port of the middle tire membrane is also internally provided with two groups of middle supporting blocks, the rear part of the middle tire membrane is provided with a rear side limiting strut, two sides of the rear side limiting strut are respectively provided with a vertically arranged rotary air cylinder, and the rotary end of the upper part of each rotary air cylinder is respectively provided with a structural form of a rotary pressing block, so that the injection molding grid is reasonable in design and compact in structure, the injection molding grid body can be automatically milled and drilled conveniently, the injection molding grids of various styles can share one die, the labor intensity and the waiting time for manually replacing the die are effectively reduced, and the production efficiency is high; and moreover, the quality of a finished product can be ensured, the mold cost and the production cost are saved, and the practicability is high.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

FIG. 2 is a schematic view of a construction of the middle tire casing of FIG. 1.

FIG. 3 is a schematic view of a structure of the side tire casing of FIG. 1.

Fig. 4 is a schematic view of a front side restraining post of fig. 1.

Fig. 5 is a schematic view of a structure of the front support block of fig. 1.

Fig. 6 is a schematic view of a construction of the middle support block of fig. 1.

Fig. 7 is a schematic view of a rear side restraining post of fig. 1.

FIG. 8 is a schematic view of a rotary press block of FIG. 1.

Fig. 9 is a schematic view of a usage status of the present invention.

The sequence numbers in the figures illustrate: 1 fetal membrane base, 2 middle fetal membranes, 3 side fetal membranes, 4 front side limiting supports, 5 front side supporting blocks, 6 middle supporting blocks, 7 rear side limiting supports, 8 rotary cylinders, 9 rotary pressing blocks, 10 base handles, 11 middle fetal membrane main bodies, 12 waste discharge ports, 13 middle positioning grooves, 14 middle fetal membrane connecting tables, 15 side fetal membrane main bodies, 16 side positioning grooves, 17 side fetal membrane connecting tables, 18 front strut main bodies, 19 front side limiting clamping grooves, 20 front strut connecting parts, 21 front strut main bodies, 22 front strut connecting parts, 23 middle strut main bodies, 24 middle strut connecting parts, 25 rear strut main bodies, 26 rear side limiting clamping grooves, 27 rear strut connecting parts, 28 pressing block main bodies, 29 rotary cylinder connecting parts, 30 workpiece pressing parts, 31 supporting frames, 32 working panels, 33 injection molding part milling tools, 34 milling tools, 35 high-speed motors, 36Z-axis shifting modules, 33 injection molding parts milling tools, 34 milling tools, 35 high-speed motors, 24 middle fetal membranes, 17 rear side limiting supports, 8 rotary cylinders, 9 rotary pressing blocks, 10 base handles, 11 middle fetal membrane main bodies, 12 waste discharge ports, 13 middle fetal membrane connecting grooves, 16 middle fetal membrane connecting tables, 16 middle fetal membrane connecting grooves, 16 middle fetal membranes, 16 middle fetal membrane connecting grooves, 17 front side locating grooves, 17 rear strut connecting grooves, 17 front side locating supporting blocks, 24 middle fetal membranes, 24 middle fetal membrane connecting blocks, 24 middle fetal membranes, 24 rear strut connecting blocks, 24 middle fetal membranes, 24 rear strut connecting parts, 30 rear strut connecting parts, 24 middle fetal membranes, 9 rear strut connecting parts, 9 rotating cylinders, 3 rear strut connecting parts, 9 rotating cylinders, 3 rear strut parts, 3 middle fetal membranes, 9 rotating cylinders, 3 middle fetal membranes, 3 middle fetal membranes, four rotating cylinders, A 37Y-axis shift module and a 38X-axis shift module.

Detailed Description

The specific structure of the present invention is described in detail with reference to fig. 1 to 9. The automatic milling tool for the injection molding part comprises a tire membrane base 1, wherein base handles 10 are respectively arranged at two ends of the tire membrane base 1, so that the whole milling tool can be conveniently mounted and dismounted on a working panel 32 of machining equipment. The middle part of the upper side of the tire membrane base 1 is provided with a middle tire membrane 2, the middle tire membrane 2 is composed of a square middle tire membrane main body 11, and the middle part of the middle tire membrane main body 11 is provided with a waste discharge port 12. A plurality of groups of middle positioning grooves 13 for stably placing injection molding pieces to be milled are respectively arranged on the middle tire membrane main body 11 and on two sides of the waste discharge port 12; the middle tire membrane main body 11 is detachably connected to the upper side of the tire membrane base 1 via middle tire membrane connecting stages 14 on both sides.

The left side and the right side of the middle tire membrane 2 are respectively symmetrically provided with a side tire membrane 3, the side tire membrane 3 is composed of a side tire membrane main body 15, a plurality of groups of side positioning grooves 16 corresponding to the middle positioning grooves 13 of the middle tire membrane 2 are arranged on the side tire membrane main body 15, and the side tire membrane main body 15 is detachably connected with the upper side of the tire membrane base 1 through a side tire membrane connecting table 17 on the side; further, the injection molding piece to be milled is stably placed on the middle tire membrane 2 and the side tire membranes 3 on the two sides by utilizing the side positioning grooves 16 on the side tire membranes 3 and the middle positioning grooves 13 on the middle tire membrane 2; and the use flexibility of the tool is increased through the detachable side part tire membranes 3 and the middle part tire membranes 2.

A group of front side limiting support columns 4 are respectively arranged in front of the side part membranes 3 on the two sides of the membrane base 1 and on the side close to the middle membrane 2. The front side limiting strut 4 is composed of a front strut main body 18 which is vertically arranged, and a front side limiting clamping groove 19 is arranged on one side, facing the side fetal membranes 3, of the front strut main body 18; the front pillar main body 18 is detachably connected with the upper side of the fetal membrane base 1 through a front pillar connecting part 20 at the lower end; therefore, the two end parts of the front side of the injection molding part to be milled, which are placed on the middle tire membrane 2 and the side tire membrane 3, are clamped and limited through the front side limiting support column 4 arranged at the front side of the side tire membrane 3 and close to one side of the middle tire membrane 2. Two sides in front of the middle part fetal membrane 2 are respectively provided with a group of front side supporting blocks 5. The front side support block 5 is composed of a rectangular parallelepiped front block main body 21, and the lower part of the front block main body 21 is detachably connected with the upper side of the tire membrane base 1 through a front block connecting part 22; to support the lower part of the front side of the injection molded article placed on the middle and side membranes 2 and 3 with the front side support block 5 provided in front of the middle membrane 2.

Meanwhile, two groups of middle supporting blocks 6 are arranged in the waste discharge port 12 in the middle of the middle tire membrane 2. The middle supporting block 6 is composed of a middle supporting block main body 23, and the middle supporting block main body 23 is detachably connected with the upper side of the tire membrane base 1 through a middle supporting block connecting part 24 so as to utilize the middle supporting block 6 arranged in the waste discharge port 12 to support the lower side of the middle part of an injection molding part placed on the middle tire membrane 2. A rear side limiting strut 7 is arranged behind the middle tire membrane 2. The rear side limiting strut 7 is composed of a rear strut main body 25, and a rear side limiting clamping groove 26 is formed in one side, facing the middle tire membrane 2, of the rear strut main body 25; the lower end of the rear pillar main body 25 is detachably connected to the upper side of the tire base 1 through a rear pillar connecting portion 27. Therefore, the rear side of the injection molding piece to be milled placed on the middle tire casing 2 is clamped and limited through the rear side limiting support 7 arranged behind the middle tire casing 2.

The two sides of the rear side limiting strut 7 are respectively and symmetrically provided with vertically arranged rotary cylinders 8, and each rotary cylinder 8 is positioned at the rotary end above the middle tire membrane 2 and is respectively provided with a rotary pressing block 9. The rotary press block 9 is composed of a press block main body 28, one end of the press block main body 28 is fixedly connected with the rotary end at the upper part of the rotary cylinder 8 through a rotary cylinder connecting part 29, and the lower side of the other end of the press block main body 28 is provided with a workpiece press fixing part 30; and then the rotating pressing block 9 is driven by the rotating cylinder 8 to rotate and lift in a reciprocating manner, so that the injection molding part to be milled is clamped and pressed by the workpiece pressing and fixing part 30 at the end part of the rotating pressing block 9.

When the automatic milling tool for the injection molding part is used, firstly, the corresponding middle tire membrane 2 and the corresponding side tire membrane 3 are selected according to the specific style of an injection molding grid product, and the middle tire membrane 2 and the side tire membrane 3 are detachably connected with the upper side of the tire membrane base 1 through the middle tire membrane connecting table 14 and the side tire membrane connecting table 17. Then, the injection molding milling tool 33 is placed on the work panel 32 on the upper portion of the machining device support frame 31 by using the base handle 10 and fixed. And then, the injection molding piece to be milled is stably placed on the middle tire membrane 2 and the side tire membranes 3 at two sides, and the two end parts and the rear side of the front side of the injection molding piece to be milled, which are placed on the middle tire membrane 2 and the side tire membranes 3, are clamped and limited through a front side limiting support 4 arranged at the front part of the side tire membranes 3 and close to one side of the middle tire membrane 2 and a rear side limiting support 7 arranged at the rear part of the middle tire membrane 2. Meanwhile, the front side support block 5 provided in front of the middle tire casing 2 and the middle support block 6 provided in the waste discharge port 12 are used to support the front and lower sides of the middle part of the injection molded part placed on the middle tire casing 2 and the side tire casing 3. And then, the rotating pressing block 9 is driven to rotate by the rotating cylinder 8, and the injection molding piece to be milled is clamped and pressed by the rotating pressing block 9, so that the injection molding piece is milled conveniently. After the injection molding piece to be milled is placed and fixed, a high-speed motor 35 of the processing equipment drives a milling cutter 34 to rotate, the milling of the injection molding piece is carried out through automatic control of the position of the milling cutter 34 through a Z-axis shifting module 36, a Y-axis shifting module 37 and an X-axis shifting module 38, and the milled waste material is discharged through a waste material discharge port 12 in the middle of the middle part of the tire membrane 2.

Claims (8)

1. The utility model provides an injection molding automatic milling frock, includes fetal membrane base (1), its characterized in that: the middle part of the upper side of the tire membrane base (1) is provided with a middle tire membrane (2), the middle tire membrane (2) is composed of a middle tire membrane main body (11), the middle part of the middle tire membrane main body (11) is provided with a waste discharge port (12), two sides of the waste discharge port (12) on the middle tire membrane main body (11) are respectively provided with a plurality of groups of middle positioning grooves (13), and the middle tire membrane main body (11) is detachably connected with the upper side of the tire membrane base (1) through middle tire membrane connecting tables (14) on the two sides; the left side and the right side of the middle part fetal membrane (2) are respectively provided with a side part fetal membrane (3), the front sides of the side part fetal membranes (3) at the two sides and one side close to the middle part fetal membrane (2) are respectively provided with a front side limiting strut (4), and the two sides of the front part of the middle part fetal membrane (2) are respectively provided with a front side supporting block (5); meanwhile, two groups of middle supporting blocks (6) are further arranged in a waste discharge port (12) of the middle tire membrane (2), a rear side limiting support column (7) is arranged behind the middle tire membrane (2), two sides of the rear side limiting support column (7) are respectively provided with vertically arranged rotary cylinders (8), and each rotary cylinder (8) is located at a rotary end above the middle tire membrane (2) and is respectively provided with a rotary pressing block (9).

2. The automatic milling tool for the injection molding part according to claim 1, is characterized in that: the side tire membrane (3) is composed of a side tire membrane main body (15), a plurality of groups of side positioning grooves (16) are arranged on the side tire membrane main body (15), and the side tire membrane main body (15) is detachably connected with the upper side of the tire membrane base (1) through a side tire membrane connecting platform (17) on the side.

3. The automatic milling tool for the injection molding part according to claim 1, is characterized in that: the front side limiting strut (4) is composed of a front strut main body (18) which is vertically arranged, and a front side limiting clamping groove (19) is formed in one side, facing the side tire membrane (3), of the front strut main body (18); and the front pillar main body (18) is detachably connected with the upper side of the fetal membrane base (1) through a front pillar connecting part (20) at the lower end.

4. The automatic milling tool for the injection molding part according to claim 1, is characterized in that: the front side supporting block (5) is composed of a cuboid front supporting block main body (21), and the lower part of the front supporting block main body (21) is detachably connected with the upper side of the fetal membrane base (1) through a front supporting block connecting part (22).

5. The automatic milling tool for the injection molding part according to claim 1, is characterized in that: the middle supporting block (6) arranged in the waste discharge port (12) of the middle tire membrane (2) is composed of a middle supporting block main body (23), and the middle supporting block main body (23) is detachably connected with the upper side of the tire membrane base (1) through a middle supporting block connecting part (24).

6. The automatic milling tool for the injection molding part according to claim 1, is characterized in that: rear side spacing pillar (7) comprise rear pillar main part (25), and rear pillar main part (25) are provided with rear side spacing draw-in groove (26) towards one side of middle part fetal membrane (2), and the lower extreme of rear pillar main part (25) passes through rear pillar connecting portion (27) and is connected with the upside of fetal membrane base (1) is detachable.

7. The automatic milling tool for the injection molding part according to claim 1, is characterized in that: the rotary pressing block (9) arranged on the rotary end of the rotary cylinder (8) is composed of a pressing block main body (28), one end of the pressing block main body (28) is fixedly connected with the rotary end of the rotary cylinder (8) through a rotary cylinder connecting part (29), and a workpiece pressing and fixing part (30) is arranged on the lower side of the other end of the pressing block main body (28).

8. The automatic milling tool for the injection molding part according to claim 1, is characterized in that: and base handles (10) are respectively arranged at two ends of the fetal membrane base (1).

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