CN221254461U - Electronic control module rotary die machine - Google Patents

Abstract

The application relates to an electronic control module rotary die machine, which comprises a cutting station and a mine distribution station, wherein a cutting seat and a cutting assembly are respectively arranged in the cutting station; a mine distributing seat is arranged in the mine distributing station and is used for installing a pipe distributing strip; and a transfer assembly is arranged between the cutting station and the mine laying station and used for transferring the electronic control module of the cutting seat to the die cavity of the mine laying strip. The electronic control module rotary die disclosed by the application can improve the working efficiency of the electronic control module rotary die.

Description

Electronic control module rotary die machine

Technical Field

The application relates to the technical field of electronic detonator assembly, in particular to an electronic control module rotary die machine.

Background

The electronic control module is usually an outsourcing part, usually 10 pieces of electronic control modules are a board, each electronic control module on the board needs to be cut out in the subsequent use of the electronic detonator, and the electronic control module is usually transferred into a standard die or arranged in a regular template for automatic assembly, and the process is called die turning or pipe laying.

Referring to fig. 1, in the conventional rotary die process, an electronic control module 8 is usually installed in a pipe distribution die by using a person, the pipe distribution die comprises a pipe distribution strip 9, and a plurality of die grooves 91 for embedding the electronic control module 8 are formed in the pipe distribution strip 9; when the production line of the electronic control modules 8 goes off line or outsources, the plurality of electronic control modules 8 are commonly connected with the connecting strips 81, and when the die is rotated, the electronic control modules 8 are pulled out of the connecting strips 81 by one hand, and the electronic control modules 8 are installed in the die grooves 91 of the pipe distribution strips 9 one by one to complete the die rotation of the electronic control modules 8.

However, such a transfer is performed manually, i.e. by pulling the electronic control module out and then into the slot of the fabric strip one after the other, which is extremely inefficient and therefore requires further improvement.

Disclosure of utility model

In order to improve the working efficiency of the electronic control module rotary die, the application provides an electronic control module rotary die machine.

The application provides an electronic control module rotary die machine which adopts the following technical scheme:

The electronic control module rotary die machine comprises a cutting station and a mine distribution station, wherein a cutting seat for installing an electronic control module and a cutting assembly for cutting a connecting strip are respectively arranged in the cutting station, and a plurality of first embedding grooves for embedding the electronic control module are formed in the top wall of the cutting seat; a mine distributing seat is arranged in the mine distributing station and is used for installing a pipe distributing strip; and a transfer assembly is arranged between the cutting station and the mine laying station and is used for transferring the electronic control module of the cutting seat to a die cavity of the pipe laying strip.

Through adopting foretell technical scheme, through cutting seat, the setting of thunder seat and transportation subassembly, when electronic control module changes the mould, place the first of cutting the seat with one row of electronic control module one-to-one and inlay and establish the groove, then cut off the connecting strip of one row of electronic control module through cutting the subassembly, thereby make one row of electronic control module separate and form independent individual, then in transferring all electronic control module to the die cavity of cloth strip through transporting the subassembly, accomplish electronic control module's commentaries on classics mould, electronic control module changes the work efficiency and the operation security of mould, improved greatly.

Optionally, the transferring assembly comprises a clamping seat, a lifting piece and a rotating piece, wherein the clamping seat is respectively provided with a fixed strip and a movable strip, the movable strip is slidably arranged on the clamping seat, and the movable strip is provided with a clamping cylinder for driving the movable strip to be close to or far away from the fixed strip; the lifting piece is arranged on the clamping seat and used for driving the clamping seat to lift, and the rotating piece is arranged on the clamping seat and used for driving the clamping seat to rotate to the mine laying station.

Through adopting the technical scheme, through the arrangement of the clamping seat, the lifting piece and the rotating piece, the movable strip is driven to move towards one side close to the fixed strip through the clamping cylinder, so that the fixed strip and the movable strip are clamped on all the electronic control modules together, then the electronic control modules are separated from the connecting strip through the cutting assembly, and then the clamping seat is lifted through the lifting piece, so that the electronic control modules are forced to be separated from the first embedded groove; then the clamping seat is driven to rotate to the mine laying station through the rotating piece, so that the electronic control module is aligned to a die groove of a pipe laying strip in the mine laying station; and finally, the clamping seat is driven to descend through the lifting piece so as to mount the electronic control module in the die cavity of the pipe distribution strip, and the die rotating convenience of the electronic control module is improved.

Optionally, a plurality of second embedded grooves are formed in the side wall, close to the fixed strip, of the movable strip, and all the second embedded grooves are arranged in one-to-one correspondence with all the first embedded grooves.

Through adopting foretell technical scheme, through the setting of groove is established to the second, a plurality of second inlays and establish the groove and supply a plurality of electronic control module to inlay one by one to establish, plays spacing effect, reduces when movable strip and fixed strip carry out the centre gripping to a plurality of electronic control module, and electronic control module's position takes place the skew and leads to follow-up a plurality of electronic control module and the possibility that the die cavity of cloth pipe strip takes place the dislocation, improves the stability of electronic control module rotary die.

Optionally, be equipped with first mount pad in the station cuts, cut the subassembly including installing in the cutting cylinder of first mount pad and install in the section of cutting the cylinder piston rod, the section just faces the connecting strip, the quantity of section is provided with a plurality of, a plurality of the section sets up along the length direction interval of connecting strip.

Through adopting foretell technical scheme, through cutting cylinder and the setting of cut piece, when cutting the connecting rod, order about the piston rod of cutting the cylinder outwards to stretch out, drive all cut pieces and remove towards one side that is close to the connecting rod to can cut the connecting rod and form the multistage, with mutual separation between all electronic control modules.

Optionally, the cutting seat is provided with a first linear motor module, and the first linear motor module is used for driving the cutting seat to move in or out of the lower part of the cutting piece.

Through adopting foretell technical scheme, through the setting of first linear motor module, will cut the seat and shift out the below of cutting the piece through first linear motor module, install a row of electronic control module in cutting the first groove of inlaying of seat afterwards, then rethread first linear motor module will cut the seat and shift into the below of cutting the piece, improve the convenience that electronic control module installed in cutting the seat.

Optionally, be equipped with the second mount pad in the mine distribution station, the pressfitting cylinder that is located the cloth pipe top is installed to the second mount pad, the piston rod of pressfitting cylinder is fixed with the plywood that is used for pressing in the electronic control module die cavity.

Through adopting foretell technical scheme, through the setting of pressfitting cylinder and laminated board, after the electronic control module after cutting shifts to the mine distribution station, order about the laminated board through the pressfitting cylinder and push down, make the laminated board with electronic control module impress in the die cavity of cloth pipe strip, improve the installation convenience between electronic control module and the cloth pipe strip.

Optionally, the mine distributing seat is provided with a limiting piece, and the limiting piece is used for enabling the pipe distributing strip to be detachably arranged on the mine distributing seat.

Through adopting foretell technical scheme, through the setting of locating part, make the cloth pipe strip demountable installation in the cloth thunder seat.

Optionally, the roof of the mine spreading seat is provided with a limit groove for embedding the pipe strips, the limit piece comprises a limit strip and a compression spring, the limit strip is installed in the limit groove in a sliding mode, the compression spring is installed between the limit groove and the limit strip, and when the pipe strips are embedded in the limit groove, the compression spring forces the limit strip to abut against the pipe strips.

Through adopting foretell technical scheme, through the setting of spacing and compression spring, when the stringing is installed, the pulling limiting plate forces limiting plate extrusion compression spring, then inlays the stringing behind the spacing inslot and loosen the limiting plate, and the limiting plate supports tightly in the lateral wall of stringing under compression spring's effect to support the stringing tightly at the inner wall of spacing groove, improve the dismouting convenience of stringing.

In summary, the present application includes at least one of the following beneficial technical effects:

1. through the arrangement of the cutting seat, the mine distributing seat and the transferring assembly, when the electronic control module rotates the die, a row of electronic control modules are correspondingly arranged in the first embedded groove of the cutting seat one by one, then the connecting strips of the row of electronic control modules are cut off through the cutting assembly, so that the row of electronic control modules are separated to form independent individuals, and then all the electronic control modules are transferred into the die grooves of the pipe distributing strips through the transferring assembly, so that the rotating die of the electronic control modules is completed, and the working efficiency and the operation safety of the rotating die of the electronic control modules are greatly improved;

2. Through the arrangement of the clamping seat, the lifting piece and the rotating piece, the movable strip is driven to move towards one side close to the fixed strip through the clamping cylinder, so that the fixed strip and the movable strip are clamped on all electronic control modules together, then the electronic control modules are separated from the connecting strip through the cutting assembly, and then the clamping seat is lifted through the lifting piece, so that the electronic control modules are forced to be separated from the first embedded groove; then the clamping seat is driven to rotate to the mine laying station through the rotating piece, so that the electronic control module is aligned to a die groove of a pipe laying strip in the mine laying station; finally, the clamping seat is driven to descend through the lifting piece, so that the electronic control module is arranged in the die groove of the pipe distribution strip, and the die rotating convenience of the electronic control module is improved;

3. Through the setting of groove is inlayed to the second, and a plurality of second inlays the groove and supplies a plurality of electronic control module to inlay one by one to establish, plays spacing effect, reduces when movable strip and fixed strip carry out the centre gripping to a plurality of electronic control module, and electronic control module's position takes place the skew and leads to the possibility that a plurality of follow-up electronic control module and the die cavity of cloth pipe strip take place the dislocation, improves the stability of electronic control module rotary die.

Drawings

FIG. 1 is a schematic diagram of a structure embodying an electronic control module and a piping strip in the background art;

FIG. 2 is a schematic overall structure of embodiment 1;

FIG. 3 is a schematic view showing the structure of a cutter assembly according to embodiment 1;

Fig. 4 is a schematic structural view showing a laminated plate according to embodiment 1;

Fig. 5 is a partial cross-sectional view of the embodiment 2 embodying a stopper.

Reference numerals illustrate: 1. a cutting station; 11. a first mount; 12. a first linear motor module; 121. a first sliding seat; 2. a mine laying station; 21. a second mounting base; 22. a second linear motor module; 221. a second sliding seat; 22. a pressing cylinder; 23. pressing the plate; 3. cutting a base; 31. a first embedded groove; 4. a cutting assembly; 41. cutting an air cylinder; 411. cutting the strips; 42. cutting into slices; 5. a mine laying seat; 51. a limiting piece; 511. a limit bar; 512. a compression spring; 513. a breaking groove; 52. a limit groove; 6. a transfer assembly; 61. a clamping seat; 611. a fixing strip; 612. a movable bar; 613. a clamping cylinder; 614. a second embedded groove; 62. a lifting cylinder; 621. a lifting plate; 63. a rotary cylinder; 7. a work table; 8. an electronic control module; 81. a connecting strip; 9. a pipe laying strip; 91. and a die cavity.

Detailed Description

The application is described in further detail below with reference to fig. 2-5.

Example 1:

the embodiment of the application discloses an electronic control module rotary die machine.

Referring to fig. 2, an electronic control module rotary die machine comprises a workbench 7, wherein a cutting station 1 and a mine distribution station 2 are respectively arranged on the upper surface of the workbench 7, the cutting station 1 is used for cutting a connecting strip 81, a row of electronic control modules 8 are separated to form a plurality of independent individuals, and the mine distribution station 2 is used for installing the plurality of cut electronic control modules 8 in a plurality of die cavities 91 of a cloth pipe 9 in a one-to-one correspondence manner, so that the rotary die of the electronic control modules 8 is completed.

Referring to fig. 2 and 3, a cutting seat 3 and a cutting assembly 4 are respectively installed in the cutting station 1, the cutting seat 3 is provided with a first linear motor module 12 (the linear motor module is a prior art means, the structure of which is not described herein too much), the first linear motor module 12 is fixedly installed on the upper surface of the workbench 7, the first linear motor module 12 is provided with a first sliding seat 121, and the first linear motor module 12 can drive the first sliding seat 121 to slide back and forth along the length direction of the first linear motor module 12; in this embodiment, the cutting seat 3 is detachably mounted on the first sliding seat 121 by means of bolting.

Referring to fig. 2 and 3, a plurality of first embedded grooves 31 are formed in the top wall of the cutting seat 3, all the first embedded grooves 31 are arranged at intervals along the length direction of the connecting strip 81, and the number of the first embedded grooves 31 is corresponding to the number of the electronic control modules 8 in a row, so that the electronic control modules 8 in a row are embedded one by one.

Referring to fig. 2 and 3, a first mounting seat 11 is fixedly mounted on the upper surface of the workbench 7, the first mounting seat 11 is located in the cutting station 1, and the cutting assembly 4 is used for cutting the connecting strip 81; the cutting assembly 4 comprises a cutting cylinder 41 and a cutting piece 42, the cutting cylinder 41 is vertically arranged, a cylinder body of the cutting cylinder 41 is fixedly arranged on the side wall of the first mounting seat 11, and a piston rod of the cutting cylinder 41 extends downwards and is connected with a cutting strip 411; the quantity of cut pieces 42 is provided with a plurality of, and a plurality of cut pieces 42 are along the length direction interval setting of connecting rod 81, and cut piece 42 is vertical setting, and the upper end fixed connection of cut piece 42 is in cut piece 411, and the lower extreme of cut piece 42 has the pointed end that is used for cutting off connecting rod 81, and the pointed end of all cut pieces 42 is all just right to connecting rod 81.

So designed, a row of electronic control modules 8 are embedded in the first embedded grooves 31 of the cutting seat 3 one by one, the cutting seat 3 is driven to move into the lower part of the cutting cylinder 41 by the first linear motor module 12, so that the cutting piece 42 is opposite to the connecting strip 81, and then the cutting piece 42 is driven to move downwards so as to cut off the connecting strip 81.

Referring to fig. 2 and 4, a mine laying seat 5 positioned at the mine laying station 2 is arranged on the upper surface of the workbench 7, and the mine laying seat 5 is used for installing a pipe laying strip 9; in this embodiment, the pipe laying strip 9 is mounted on the top wall of the mine laying seat 5 by means of bolt fixing, and it should be noted that, when the pipe laying strip 9 is mounted, a through hole for the bolt to pass through needs to be formed in the side wall of the pipe laying strip 9; the mine distribution seat 5 is provided with a second linear motor module 22, the second linear motor module 22 is fixedly arranged on the upper surface of the workbench 7, the second linear motor module 22 is provided with a second sliding seat 221, the second linear motor module 22 can drive the first sliding seat 121 to slide back and forth along the length direction of the second linear motor module 22, and the length direction of the second linear motor module 22 is consistent with the length direction of the first linear motor module 12; in this embodiment, the mine base 5 is detachably mounted on the second sliding base 221 by means of bolting.

Referring to fig. 2 and 3, a transferring assembly 6 is installed between the cutting station 1 and the mine laying station 2, and the transferring assembly 6 is used for transferring the electronic control module 8 of the cutting seat 3 to the die cavity 91 of the mine laying strip 9; the transferring assembly 6 comprises a clamping seat 61, a lifting piece and a rotating piece, wherein the clamping seat 61 is used for clamping and fixing the electronic control module 8, the lifting piece is used for driving the clamping seat 61 to lift, and the rotating piece is used for driving the clamping seat 61 to rotate to the mine distribution station 2.

Referring to fig. 2, in the present embodiment, the lifting member is configured as a lifting cylinder 62, the lifting cylinder 62 is vertically disposed, a cylinder body of the lifting cylinder 62 is fixedly mounted on a bottom wall of the workbench 7, and a piston rod of the lifting cylinder 62 penetrates through an upper surface of the workbench 7 and is fixedly connected with a lifting plate 621; the rotating piece is provided as a rotary air cylinder 63, the cylinder body of the rotary air cylinder 63 is fixedly arranged on the top wall of the lifting plate 621, and the output end of the rotary air cylinder 63 is fixedly connected with the clamping seat 61; the holder 61 can be lifted and rotated by a lifting cylinder 62 and a rotating cylinder 63.

Referring to fig. 3 and 4, the clamping seat 61 is respectively provided with a fixed bar 611 and a movable bar 612, the fixed bar 611 is fixedly arranged on the side wall of the clamping seat 61, and the movable bar 612 is slidably arranged on the side wall of the clamping seat 61 and can be close to or far from the fixed bar 611; a clamping cylinder 613 is mounted on the side wall of the clamping seat 61, and a piston rod of the clamping cylinder 613 is connected to the movable bar 612 for driving the movable bar 612 to approach or separate from the fixed bar 611; a plurality of second embedded grooves 614 are formed on the side wall of the movable strip 612 close to the fixed strip 611, and all the second embedded grooves 614 are arranged in one-to-one correspondence with all the first embedded grooves 31.

Referring to fig. 2 and 4, a second mounting seat 21 positioned in the mine distribution station 2 is fixedly mounted on the upper surface of the workbench 7, a pressing cylinder 22 is mounted on the second mounting seat 21, the pressing cylinder 22 is positioned above the mine distribution strip 9, a cylinder body of the pressing cylinder 22 is fixedly mounted on the side wall of the second mounting seat 21, a piston rod of the pressing cylinder 22 extends downwards and is fixedly connected with a pressing plate 23, and the pressing plate 23 is used for pressing the electronic control module 8 into the die cavity 91; it should be noted that, after the electronic control module 8 moves right above the cloth pipe 9 under the action of the rotary cylinder 63, the lifting cylinder 62 drives the electronic control module 8 to move down, and the pressing cylinder 22 drives the pressing plate 23 to press down, so that the electronic control module 8 is pressed into the die cavity 91 of the cloth pipe 9 under the combined action of the pressing plate 23 and the clamping seat 61.

The implementation principle of the embodiment 1 of the application is as follows: a row of electronic control modules 8 are embedded in the first embedded groove 31 of the cutting seat 3 one by one, and are moved below the cutting piece 42 through the first linear motor module 12, then one end, far away from the connecting strip 81, of the electronic control modules 8 is clamped and fixed through the fixed strip 611 and the movable strip 612 of the clamping seat 61, and the cutting piece 42 is driven to be cut down on the connecting strip 81, so that the cutting operation of the electronic control modules 8 is completed; after cutting, the clamping seat 61 is lifted by the lifting cylinder 62, so that the electronic control module 8 is separated from the first embedding groove 31, then the electronic control module 8 is rotated to the mine distribution station 2 by the rotary cylinder 63, the electronic control module 8 is positioned right above the pipe distribution strip 9, and finally the electronic control module 8 is installed in the die cavity 91 of the pipe distribution strip 9 by pressing the pressing plate 23 downwards and shrinking the lifting cylinder 62, so that the die rotating of the electronic control module 8 is completed, and the working efficiency of the die rotating of the electronic control module 8 is greatly improved.

Example 2:

the embodiment of the application discloses an electronic control module rotary die machine.

Referring to fig. 5, the difference between the electronic control module rotary die machine disclosed in the embodiment of the application and the embodiment 1 is that:

In this embodiment, the top wall of the mine-laying seat 5 is provided with a limit groove 52, the limit groove 52 is used for embedding the tube-laying strip 9, and when the tube-laying strip 9 is embedded in the limit groove 52, the tube-laying strip 9 is partially exposed out of the limit groove 52; a limiting piece 51 for enabling the pipe laying strip 9 to be detachably mounted on the mine laying seat 5 is mounted in the limiting groove 52.

Referring to fig. 5, the limiting member 51 includes a limiting bar 511 and a compression spring 512, the limiting bar 511 is slidably mounted in the limiting groove 52, a breaking groove 513 is formed in a top wall of the limiting bar 511, and the breaking groove 513 is used for allowing an operator to extend in to drive the limiting bar 511 to slide; the compression spring 512 is installed between the spacing groove 52 and the spacing 511, one end of the compression spring 512 is fixedly connected to the side wall of the spacing groove 52, the other end of the compression spring 512 is fixedly connected to the spacing 511, the spacing 511 is slidably installed in the spacing groove 52 through the compression spring 512, and when the pipe laying strip 9 is embedded in the spacing groove 52, the compression spring 512 forces the spacing 511 to be abutted against the pipe laying strip 9.

The implementation principle of the embodiment 2 of the application is as follows: when the cloth tube strip 9 is installed, the limit strip 511 is broken off to force the limit strip 511 to extrude the compression spring 512, then the cloth tube strip 9 is placed into the limit groove 52, then the limit strip 511 is loosened, the limit strip 511 is abutted against the cloth tube strip 9 under the action of the compression spring 512, and therefore the side walls of the limit strip 511 and the limit groove 52 can be clamped and fixed on the cloth tube strip 9 together, and the disassembly and assembly convenience of the cloth tube strip 9 is improved.

The above is a preferred embodiment of the present application, and is not intended to limit the scope of the present application in this way, therefore: all equivalent changes in structure, shape and principle of the application should be covered in the scope of protection of the application.

Claims (8)

1. An electronic control module rotary die machine which is characterized in that: the automatic cutting device comprises a cutting station (1) and cloth Lei Gongwei (2), wherein a cutting seat (3) for installing an electronic control module (8) and a cutting assembly (4) for cutting a connecting strip (81) are respectively arranged in the cutting station (1), and a plurality of first embedding grooves (31) for embedding the electronic control module (8) are formed in the top wall of the cutting seat (3); a mine distributing seat (5) is arranged in the mine distributing station (2), and the mine distributing seat (5) is used for installing a pipe distributing strip (9); a transferring component (6) is arranged between the cutting station (1) and the cloth Lei Gongwei (2), and the transferring component (6) is used for transferring an electronic control module (8) of the cutting seat (3) to a die cavity (91) of the cloth pipe strip (9).

2. An electronic control module rotary die machine as defined in claim 1, wherein: the transfer assembly (6) comprises a clamping seat (61), a lifting piece and a rotating piece, wherein the clamping seat (61) is respectively provided with a fixed strip (611) and a movable strip (612), the movable strip (612) is slidably arranged on the clamping seat (61), and the movable strip (612) is provided with a clamping cylinder (613) for driving the movable strip (612) to be close to or far away from the fixed strip (611); the lifting piece is arranged on the clamping seat (61) and used for driving the clamping seat (61) to lift, and the rotating piece is arranged on the clamping seat (61) and used for driving the clamping seat (61) to rotate to the mine laying station (2).

3. An electronic control module rotary die machine as defined in claim 2, wherein: a plurality of second embedded grooves (614) are formed in the side wall, close to the fixed strip (611), of the movable strip (612), and all the second embedded grooves (614) are in one-to-one correspondence with all the first embedded grooves (31).

4. An electronic control module rotary die machine as defined in claim 1, wherein: the utility model discloses a cutting station, including cutting station (1), cutting assembly (4) including install in cutting cylinder (41) of first mount pad (11) and install in cutting section (42) of cutting cylinder (41) piston rod, cutting section (42) are just to connecting strip (81), the quantity of cutting section (42) is provided with a plurality ofly, a plurality of cutting section (42) are along the length direction interval setting of connecting strip (81).

5. The electronic control module rotary die machine as defined in claim 4, wherein: the cutting seat (3) is provided with a first linear motor module (12), and the first linear motor module (12) is used for driving the cutting seat (3) to move in or out of the lower part of the cutting piece (42).

6. An electronic control module rotary die machine as defined in claim 1, wherein: the mine laying station (2) is internally provided with a second mounting seat (21), the second mounting seat (21) is provided with a pressing cylinder (22) positioned above the mine laying strip (9), and a piston rod of the pressing cylinder (22) is fixed with a pressing plate (23) for pressing the electronic control module (8) into the die cavity (91).

7. An electronic control module rotary die machine as defined in claim 1, wherein: the mine laying seat (5) is provided with a limiting piece (51), and the limiting piece (51) is used for enabling the pipe laying strip (9) to be detachably arranged on the mine laying seat (5).

8. The electronic control module rotary die machine as recited in claim 7, wherein: limiting grooves (52) for embedding the pipe strips (9) are formed in the top wall of the mine distributing seat (5), each limiting piece (51) comprises a limiting strip (511) and a compression spring (512), each limiting strip (511) is slidably installed in each limiting groove (52), each compression spring (512) is installed between each limiting groove (52) and each limiting strip (511), and when the pipe strips (9) are embedded in the corresponding limiting grooves (52), each limiting strip (511) is forced to be abutted against the corresponding pipe strip (9) by the corresponding compression spring (512).