CN210754722U - Automatic punching forming mechanism for bicolor oxide three-head cutter - Google Patents

Abstract

The utility model provides a double-colored oxidation three-head knife automatic punching forming mechanism belongs to machining technical field. It has solved the inconvenient, the loaded down with trivial details scheduling problem of mould change of current automatic punching forming mechanism positioning adjustment. This automatic die-cut forming mechanism of bicolor oxidation triceps sword, including the fuselage and set up the workstation on the fuselage, still be provided with the punching press head that is located the workstation top on the fuselage, be provided with on the workstation with punching press head matched with mould seat, offer the standing groove that is used for placing different modules on the mould seat, the both sides tip of mould seat is provided with the anchor clamps subassembly that is used for the mould seat to fix. The utility model has the advantages of convenient positioning adjustment and rapid module installation.

Description

Automatic punching forming mechanism for bicolor oxide three-head cutter

Technical Field

The utility model belongs to the technical field of machining, a automatic die-cut forming mechanism of bicolor oxidation three-head knife is related to.

Background

The punching machine is a punching press, in national production, the punching process has the advantages of material and energy saving, high efficiency, low technical requirement on operators and capability of manufacturing products which cannot be achieved by machining through various die applications compared with the traditional machining, so that the punching press is more and more widely used.

Along with the continuous improvement of market demand, stamping die's structure is also more and more complicated, needs a series of processes to accomplish complete processing usually, and traditional punching press processing mode, manufacturing procedure is many, and the procedure is long, needs a lot of transportation, needs clamping, repeated location many times at the dismouting in-process, and is comparatively loaded down with trivial details, and because clamping location at every turn is inconsistent, leads to the work piece machining precision poor easily.

SUMMERY OF THE UTILITY MODEL

The utility model aims at the above-mentioned problem, provide a location adjustment is convenient, the swift automatic die-cut forming mechanism of double-colored oxidation three-head knife of module installation.

In order to achieve the above purpose, the utility model adopts the following technical proposal:

the utility model provides a double-colored three-head cutter automatic punching forming mechanism, includes the fuselage and sets up the workstation on the fuselage, the fuselage on still be provided with the punching press head that is located the workstation top, its characterized in that, the workstation on be provided with punching press head matched with mould seat, the mould seat on offer the standing groove that is used for placing different modules, the both sides tip of mould seat be provided with and be used for the fixed anchor clamps subassembly of mould seat.

In the automatic punching and forming mechanism for the bicolor oxide three-head cutter, the clamp assembly comprises a positioning rod arranged on the workbench and a clamping block connected to the positioning rod, one end of the clamping block abuts against the mold base, and a cushion block is connected between the other end of the clamping block and the workbench.

In the automatic punching and forming mechanism for the bicolor oxide three-head cutter, the workbench is provided with a slot for inserting the positioning rod, and the positioning rod and the workbench are perpendicular to each other.

In the automatic punching and forming mechanism for the bicolor oxide three-head cutter, the positioning rod is provided with a lower connecting part with a smooth outer wall and an upper connecting part with threads processed on the outer wall, and a locking piece used for locking the clamping block is arranged on the upper connecting part.

In the automatic punching and forming mechanism for the bicolor oxide three-head cutter, the clamping block is in a curved arch shape, the top end face of the clamping block is provided with a connecting groove for the connecting part on the positioning rod to pass through, and the connecting groove penetrates through the whole clamping block from top to bottom.

In foretell double-colored oxidation triceps blade automatic punching forming mechanism, the locking piece including be used for with last connecting portion matched with connecting block and link firmly the cooperation piece in the tip under the connecting block, connecting block and last connecting portion looks spiro union, the cooperation piece insert in the spread groove with spread groove sliding connection.

In the automatic punching and forming mechanism for the bicolor oxide three-head cutter, the length of the connecting groove is greater than that of the matching block, and the connecting grooves are distributed along the length direction of the clamping block.

In the automatic punching and forming mechanism for the bicolor oxide three-head cutter, the top end part of the clamping block is also provided with a matching groove which is recessed downwards, the width of the matching groove is wider than that of the connecting groove, and a step surface for the matching block to abut against is formed between the matching groove and the connecting groove.

In foretell double-colored oxidation triceps automatic punching forming mechanism, the preceding terminal surface of mould seat on be provided with standing groove matched with place the component, place the component include with link firmly the fixing base on the mould seat, the fixing base on be provided with monkey wrench and rotate the movable rod of being connected with monkey wrench, the movable rod on be equipped with and stretch into the abaculus to the standing groove in.

In the automatic punching and forming mechanism for the bicolor oxide three-head cutter, the adjustable wrench and the movable rod are hinged with the fixed seat, the tail parts of the adjustable wrench and the movable rod are provided with gears in meshing transmission, and the embedded block and the movable rod are detachably connected.

Compared with the prior art, the utility model has the advantages of:

1. offer the standing groove that is used for placing different modules on the mould seat, according to the different demands of work piece, can place corresponding module in the standing groove, avoid the problem of the repeated dismouting of mould seat.

2. The clamp assembly comprises a positioning rod and a clamping block, the clamping block is connected to the positioning rod through a locking piece, one end of the clamping block is abutted to the die seat, and a cushion block is connected between the other end of the clamping block and the workbench, so that the clamp assembly is convenient to disassemble and assemble.

3. The clamping block is in a bent arch shape, a connecting groove for the connecting part on the positioning rod to penetrate through is formed in the top end face of the clamping block, the connecting groove is distributed along the length direction of the clamping block, and when the clamping block is matched with the positioning rod, fine adjustment of the position of the clamping block relative to the positioning rod can be conducted according to different sizes of workpieces.

4. Be provided with on the preceding terminal surface of mould seat with standing groove matched with place the component, insert the not unidimensional cushion through placing the component and be used for the processing of different work pieces in the standing groove, convenient and fast need not to change the mould seat.

Additional advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the invention.

Drawings

Fig. 1 is a schematic diagram of the overall structure of the present invention.

Fig. 2 is a schematic structural diagram of the middle clamping block of the present invention.

Fig. 3 is a schematic structural diagram of the placement member of the present invention.

In the figure, 1, a fuselage; 2. a work table; 3. punching a head; 4. a mold base; 5. a placement groove; 6. a clamp assembly; 7. positioning a rod; 8. a clamping block; 9. cushion blocks; 10. a slot; 11. a lower connecting portion; 12. an upper connecting portion; 13. a locking member; 14. connecting grooves; 15. connecting blocks; 16. a matching block; 17. a mating groove; 18. a step surface; 19. placing a component; 20. a fixed seat; 21. an adjustable wrench; 22. a movable rod; 23. an insert block; 24. a gear.

Detailed Description

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

As shown in fig. 1 to 3, an automatic punching and forming mechanism for a bicolor oxide three-head cutter comprises a machine body 1 and a workbench 2 arranged on the machine body 1, wherein a punching head 3 positioned above the workbench 2 is further arranged on the machine body 1, a mold seat 4 matched with the punching head 3 is arranged on the workbench 2, a placing groove 5 for placing different modules is arranged on the mold seat 4, and clamp assemblies 6 for fixing the mold seat 4 are arranged at the end parts of two sides of the mold seat 4.

Automatic die-cut forming mechanism is before using, realize the location through anchor clamps subassembly 6 earlier to mould seat 4 fixed, let mould seat 4 be in the below of punching press head 3, the work piece on punching press head 3 downstream punching press mould seat 4 accomplishes the stamping process with this, in order to reduce the precision that 4 repeated dismouting location influences processing of mould seat, standing groove 5 has been seted up on the mould seat 4, can be used to place the module of various different shapes in the standing groove 5, the required shape is punched into through the shape of module, the module can be taken fast, and the advantages of convenient and fast have.

In the above embodiments, the clamp assembly 6 may be a bolt or a cylinder, and the mold base 4 is fixed to the worktable 2 by using a plurality of bolts, or the cylinder is activated, and the mold base 4 is pressed and fixed to the worktable 2 by using the pressure of the cylinder.

Preferably, in the present embodiment, the jig assembly 6 includes a positioning rod 7 provided on the table 2 and a clamp block 8 connected to the positioning rod 7, one end of the clamp block 8 abuts on the die holder 4, and a spacer 9 is connected between the other end of the clamp block 8 and the table 2. The clamping block 8 is arranged on the positioning seat, the cushion blocks 9 are arranged between one end of the clamping block 8 and the workbench 2, and the number of the cushion blocks 9 can be adjusted according to the specific height of the die seat 4, so that the purpose of balancing two ends is achieved.

In more detail, the workbench 2 is provided with a slot 10 for inserting the positioning rod 7, and the positioning rod 7 is perpendicular to the workbench 2. The positioning rod 7 is arranged in the slot 10, so that the stability of the positioning rod 7 can be improved, the deviation is prevented, the positioning rod 7 is perpendicular to the workbench 2, and the locking block is more conveniently connected and fixed with the positioning rod 7.

Referring to fig. 1, the positioning rod 7 has a lower connecting portion 11 with a smooth outer wall and an upper connecting portion 12 with a thread formed on the outer wall, and the upper connecting portion 12 is provided with a locking member 13 for locking the clamping block 8. The locking piece 13 is screwed with the upper connecting part 12 of the positioning rod 7 to fix the clamping block 8, and the locking piece 13 is convenient to detach.

As shown in fig. 2, the clamping block 8 has a curved arch shape, a connecting groove 14 through which the connecting portion 12 of the positioning rod 7 passes is provided on the top end surface of the clamping block 8, and the connecting groove 14 penetrates the entire clamping block 8 from top to bottom. When both ends of the arched clamping block 8 are stressed, the stress distribution is more balanced, and the connecting groove 14 is used for enabling the clamping block 8 to slide transversely relative to the positioning rod 7 when the clamping block is positioned and clamped.

Preferably, the locking member 13 includes a connecting block 15 for cooperating with the upper connecting portion 12 and a cooperating block 16 fixedly connected to a lower end portion of the connecting block 15, the connecting block 15 is screwed with the upper connecting portion 12, the cooperating block 16 is inserted into the connecting groove 14 to be slidably connected with the connecting groove 14, the length of the connecting groove 14 is greater than that of the cooperating block 16, when the locking member 13 is installed, the clamping block 8 can be shifted relative to the cooperating block 16 through the connecting groove 14, and the cooperating block 16 is used for preventing the clamping block 8 from rotating.

The top end of the clamping block 8 is further provided with a matching groove 17 recessed downwards, the width of the matching groove 17 is wider than that of the connecting groove 14, a step surface 18 for the matching block 16 to abut against is formed between the matching groove 17 and the connecting groove 14, when the matching block 16 is installed, the bottom end surface of the matching block 16 abuts against the lower end surface of the matching groove 17 to be fitted, the matching block 16 is integrally accommodated on the formed step surface 18, and the clamping block 8 is connected with the matching block 16 through the matching of the matching groove 17, so that the clamping block 8 is more stable in fine adjustment movement.

Referring to fig. 1 and 3, a placing member 19 matched with the placing groove 5 is disposed on the front end surface of the mold base 4, and the placing member 19 may be a robot arm composed of an air cylinder or an oil cylinder understood by those skilled in the art, and the air cylinder or the oil cylinder is used to drive the robot arm to place the module.

Preferably, in this example, as shown in fig. 3, the placing member 19 includes a fixed seat 20 fixedly connected to the mold base 4, a movable wrench 21 and a movable rod 22 rotatably connected to the movable wrench 21 are disposed on the fixed seat 20, and an insert 23 capable of extending into the placing groove 5 is disposed on the movable rod 22. The placing component 19 is used for placing the insert 23 into the placing groove 5 for punch forming of products with different shapes, the adjustable wrench 21 is movably connected with the movable rod 22, when the adjustable wrench 21 is pulled to one side, the movable rod 22 can rotate to the opposite side direction, and the insert 23 arranged at the end part of the movable rod 22 is inserted into the placing groove 5.

Referring to fig. 3, the adjustable wrench 21 and the movable rod 22 are both hinged to the fixed base 20, a gear 24 for meshing transmission is disposed at the tail of the adjustable wrench 21 and the movable rod 22, and the insert 23 is detachably connected to the movable rod 22. The adjustable spanner 21 is hinged to the fixed seat 20 with the tail end of the movable rod 22 to realize rotation of the adjustable spanner and the fixed seat, transmission is realized through meshing of the gears 24, transmission precision is improved, and the embedded block 23 is detachably connected with the movable rod 22 to facilitate timely replacement of the embedded block 23.

The utility model discloses a theory of operation does: before the automatic punching forming mechanism is used, the die seat 4 is positioned and fixed through the clamp assembly 6, the die seat 4 is positioned below the punching head 3, the clamping block 8 is inserted into the positioning rods 7 arranged at the two side ends of the die seat 4, then the locking piece 13 is screwed in to pre-fix the clamping block 8, one end of the clamping block 8 is abutted against the die seat 4, the other end of the clamping block 8 adjusts the quantity of the cushion blocks 9 according to the relative height of the clamping block 8 and the die seat 4, so that the two ends of the clamping block 8 are positioned at the relatively horizontal position, meanwhile, the positioning point of the clamping block 8 on the die seat 4 is determined by utilizing the sliding of the connecting groove 14 on the clamping block 8 relative to the positioning rods 7, finally, the clamping block 8 is fixed through the locking piece 13, after the die seat 4 is completely fixed, the punching head 3 moves downwards to punch a workpiece on the die seat 4 so as to complete the punching process, in order to reduce the complicated processes of, the mould seat 4 is provided with a placing groove 5, the front end face of the mould seat 4 is provided with a placing component 19 matched with the placing groove 5, when the adjustable wrench 21 is wrenched to one side, the movable rod 22 can rotate to the opposite side direction, and the embedded block 23 arranged at the end part of the movable rod 22 is inserted into the placing groove 5.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications, additions and substitutions for the specific embodiments described herein may be made by those skilled in the art without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Although the terms of the body 1, the table 2, the punch 3, the die holder 4, the placing groove 5, the jig assembly 6, the positioning rod 7, the clamping block 8, the spacer block 9, the insertion groove 10, the lower connecting portion 11, the upper connecting portion 12, the locking member 13, the connecting groove 14, the connecting block 15, the fitting block 16, the fitting groove 17, the stepped surface 18, the placing member 19, the fixing seat 20, the monkey wrench 21, the movable rod 22, the insert block 23, the gear 24, etc. are used more frequently herein, the possibility of using other terms is not excluded. These terms are used merely to more conveniently describe and explain the nature of the present invention and should not be interpreted as imposing any additional limitations that are contrary to the spirit of the present invention.

Claims (10)

1. The utility model provides a two-color oxidation triceps sword automatic punching forming mechanism, includes fuselage (1) and sets up workstation (2) on fuselage (1), fuselage (1) on still be provided with stamping head (3) that are located workstation (2) top, a serial communication port, workstation (2) on be provided with stamping head (3) matched with mould seat (4), mould seat (4) on offer standing groove (5) that are used for placing different modules, the both sides tip of mould seat (4) be provided with and be used for the fixed anchor clamps subassembly (6) of mould seat (4).

2. The automatic punching and forming mechanism of the bicolor oxide three-head cutter according to claim 1, wherein the clamp assembly (6) comprises a positioning rod (7) arranged on the workbench (2) and a clamping block (8) connected to the positioning rod (7), one end of the clamping block (8) abuts against the mold base (4), and a cushion block (9) is connected between the other end of the clamping block (8) and the workbench (2).

3. The automatic punching and forming mechanism of the bicolor oxide three-head cutter according to claim 2, wherein the workbench (2) is provided with a slot (10) for inserting the positioning rod (7), and the positioning rod (7) and the workbench (2) are arranged in a mutually perpendicular manner.

4. The automatic punching and forming mechanism of the bicolor oxide three-head cutter as claimed in claim 2, wherein the positioning rod (7) is provided with a lower connecting part (11) with a smooth outer wall and an upper connecting part (12) with a thread on the outer wall, and a locking piece (13) for locking the clamping block (8) is arranged on the upper connecting part (12).

5. The automatic punching and forming mechanism of the bicolor oxide triceps blade of claim 4, characterized in that the clamping block (8) is in a curved arch shape, the top end surface of the clamping block (8) is provided with a connecting groove (14) for the connecting part (12) of the positioning rod (7) to pass through, and the connecting groove (14) penetrates through the whole clamping block (8) from top to bottom.

6. The automatic punching and forming mechanism of the bicolor oxide tricuspid knife according to claim 5, wherein the locking piece (13) comprises a connecting block (15) used for being matched with the upper connecting part (12) and a matching block (16) fixedly connected to the lower end part of the connecting block (15), the connecting block (15) is in threaded connection with the upper connecting part (12), and the matching block (16) is inserted into the connecting groove (14) and is in sliding connection with the connecting groove (14).

7. The automatic punching and forming mechanism of the bicolor oxide tricuspid cutter according to claim 6, characterized in that the length of the connecting groove (14) is greater than that of the matching block (16), and the connecting grooves (14) are distributed along the length direction of the clamping block (8).

8. The automatic punching and forming mechanism of the bicolor oxide triceps blade of claim 6, characterized in that the top end part of the clamping block (8) is further provided with a matching groove (17) which is recessed downwards, the width of the matching groove (17) is wider than that of the connecting groove (14), and a step surface (18) for the matching block (16) to abut against is formed between the matching groove (17) and the connecting groove (14).

9. The automatic punching and forming mechanism of the bicolor oxide triceps blade according to claim 1, wherein a placing member (19) matched with the placing groove (5) is arranged on the front end face of the die holder (4), the placing member (19) comprises a fixed seat (20) fixedly connected to the die holder (4), a movable wrench (21) and a movable rod (22) rotatably connected with the movable wrench (21) are arranged on the fixed seat (20), and an embedded block (23) capable of extending into the placing groove (5) is arranged on the movable rod (22).

10. The automatic punching and forming mechanism of the bicolor oxide triceps blade of claim 9, wherein the adjustable wrench (21) and the movable rod (22) are hinged with the fixed seat (20), a gear (24) for meshing transmission is arranged at the tail parts of the adjustable wrench (21) and the movable rod (22), and the embedded block (23) is detachably connected with the movable rod (22).

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