CN112387898B - Shaping device for shaping plug-in components into mounted components - Google Patents

Abstract

The invention provides a shaping device for shaping a plug-in component into a mounting component, which comprises a frame (1), wherein a base (2) is arranged on the frame (1) and is characterized in that: be equipped with feeding subassembly (8) that the slant distributes on base (2), be equipped with first guide slot (3) on base (2) of feeding subassembly (8) one side, be equipped with on base (2) with first guide slot (3) correspond complex first pushing component (4), second guide slot (5) with first guide slot (3) intercommunication on base (2), be equipped with on base (2) with second guide slot (5) correspond complex second pushing component (6), be equipped with in the frame of second guide slot (5) top with second guide slot (5) correspond complex plastic cutting component (7). The invention has the advantages of simple structure, convenient use, good shaping and cutting effects of components, high working efficiency and the like.

Description

Shaping device for shaping plug-in components into mounted components

Technical field:

the invention relates to the technical field of surface assembly in a hybrid integrated circuit, in particular to a shaping device for shaping a plug-in component into a mounting component.

The background technology is as follows:

surface Mount Technology (SMT) refers to an assembly technique in which components are surface-mounted soldered to prescribed locations on a substrate surface. Some component packages are in the form of dual in-line (DIP) packages due to differences in component packages or material procurement channels.

Because of the circuit function design requirements, such as the substrate strength, the circuit heat dissipation, the high reliability, the coefficient of thermal expansion CTE of the substrate and the components, the circuit high density integration and the like, the circuit substrate needs to be made of ceramic materials, the metallized through hole processing technology cannot be realized in the ceramic material film forming preparation technology, and the dual in-line package (DIP) cannot be directly used. In the process catalog of the product forbidden (limit) technology of Q/RJ 557-2017 aerospace model, the 74 th component lead wire forming process of the electrical installation process is specified as follows: "inhibit shaping with common tools such as tweezers; the surface mount device leads are prohibited from adopting a tooling-free forming process. At present, the manual and simple tool shaping is adopted, so that the problems of low efficiency, inconsistent external dimensions after shaping and the like exist, and batch automatic production cannot be realized.

The invention comprises the following steps:

the invention aims to overcome the defects in the prior art and provides a shaping device for shaping a plug-in component into a mounting component.

The application provides the following technical scheme:

the utility model provides a plastic device with cartridge components and parts plastic for mounting components and parts, it includes the frame, is equipped with base its characterized in that in the frame: the feeding assembly is arranged on the base in an inclined mode, a first guide groove is formed in the base on one side of the feeding assembly, a first pushing assembly which is correspondingly matched with the first guide groove is arranged on the base, a second guide groove which is communicated with the first guide groove is further formed in the base, a second pushing assembly which is correspondingly matched with the second guide groove is arranged on the base, a shaping cutting assembly which is correspondingly matched with the second guide groove is arranged on a frame above the second guide groove, and a console which is correspondingly matched with the first pushing assembly, the second pushing assembly and the shaping cutting assembly in an electric signal connection control mode is further arranged on one side of the frame.

On the basis of the technical scheme, the following further technical scheme is also available:

the feeding assembly comprises a supporting seat arranged on a base at one side of a first guide groove, a bottom plate is fixedly connected to the top end of the supporting seat, one end of the bottom plate is in contact with the base, the other end of the bottom plate is tilted upwards, through grooves are formed in the end parts of two ends of the bottom plate, guide strips axially distributed along the bottom plate are arranged in the two through grooves in a penetrating mode, the upper sides of the guide strips are fixedly connected with the bottoms of the through grooves, a certain distance is reserved between the lower sides of the guide strips and the bottom plate at intervals, guide plates are respectively arranged on the bottom plates at the left side and the right side of the middle of the guide strips, shaping blocks are outwards symmetrically protruded on the side walls of two sides of the guide strips at one side of the guide plates, and third guide grooves communicated with the first guide grooves are formed in the base at one end of the bottom plate.

The first pushing assembly comprises a first cylinder bracket connected to a base at one end of the first guide groove, a first cylinder which is output along the direction of the first guide groove is arranged on the first cylinder bracket, an L-shaped first pushing rod is connected to the output end of the first cylinder, the first pushing rod comprises a vertical section and a horizontal section, the vertical section is connected with the output end of the first cylinder, and the horizontal section is positioned in the first guide groove and forms sliding fit with the first cylinder; the base at one side of the first cylinder support is also provided with a first limit support, and the first limit support is provided with a first stop block which is in limit fit with the vertical section of the pushing rod.

The second pushing component comprises a second cylinder support connected to a base at one end of the second guide groove, a second cylinder outputting along the direction of the second guide groove is arranged on the second cylinder support, an L-shaped second pushing rod is connected to the output end of the second cylinder, the second pushing rod also comprises a vertical section and a horizontal section, the vertical section is connected with the output end of the second cylinder, the horizontal section is located in the second guide groove and forms sliding fit with the second guide groove, and a second limiting block corresponding to the output end of the second cylinder is further arranged on the second guide groove in a crossing mode.

The shaping and cutting assembly comprises a cylinder which is vertically distributed on a frame, a movable plate is connected to an output shaft of the cylinder through a connecting seat, an upper die holder is connected to the bottom surface of the movable plate, a first punching head, a second punching head and a cutting head are sequentially connected to the upper die holder along the axial direction of a second guide groove, a group of guide rods are further arranged on the movable plate on one side of the upper die holder in a penetrating mode, and buffer springs are further arranged on the guide rods between the movable plate and the base in a penetrating mode.

The base on one side of the second guide groove is provided with a support, the support is connected with a blowing pipe, the air outlet end of the blowing pipe is positioned on one side of the shaping and cutting device and is opposite to the second guide groove, the axial direction of the blowing pipe is in an acute angle with the bottom surface of the second guide groove, one section of the blowing pipe is communicated with an air source through the air pipe, the air pipe is also provided with a control valve which is correspondingly matched, and the control valve is in electric signal connection control matching with a control console through a lead.

The cantilever which extends outwards is connected to the connecting seat, the guide rod is arranged on the frame above the cantilever in a penetrating mode, and the lower end of the guide rod is connected with the cantilever in a matching mode.

The blanking hole penetrates through the base and the bottom plate of the frame, and a receiving frame which is distributed correspondingly to the blanking hole is arranged below the bottom plate of the frame.

The invention has the advantages that:

the invention has the advantages of simple structure, convenient use, good component shaping effect, small component shaping and cutting error, high working efficiency, reduced labor intensity, meeting the requirement of batch automatic mounting and the like.

Description of the drawings:

FIG. 1 is a front view of the present invention;

FIG. 2 is a schematic perspective view of FIG. 1;

FIG. 3 is a schematic perspective view of the frame with the uprights and upper components thereof removed;

FIG. 4 is a schematic view of the other direction of FIG. 3;

FIG. 5 is an enlarged view in direction A of FIG. 3;

FIG. 6 is an enlarged view of FIG. 4 in the direction B;

FIG. 7 is a schematic view showing the distribution of the first, second and third guide grooves according to the present invention;

FIG. 8 is a schematic diagram of a pin of a component during secondary shaping;

FIG. 9 is a schematic diagram of a pin of a component when three reshaping operations are performed;

fig. 10 is a schematic diagram of the pins of the component at the time of blanking.

The specific embodiment is as follows:

as shown in fig. 1-10, a shaping device for shaping a mounted component into a mounted component comprises a frame 1, wherein the frame 1 comprises a frame bottom plate 1a, supporting legs 1b are arranged on the bottom surface of the frame bottom plate 1a, a group of upright posts 1c which are vertically distributed are not arranged on the upper surface of the frame bottom plate 1a, and a top plate 1d corresponding to the frame bottom plate 1a is connected to the top end of each upright post 1 c.

A rectangular base 2 which is horizontally distributed is fixedly connected to the bottom plate 1a of the frame, and a feeding assembly 8 is fixedly connected to the upper surface close to the right width edge of the base 2. The feeding assembly 8 comprises a supporting seat 8a connected with the base 2 through bolts, an inclined plane is arranged at the top end of the supporting seat 8a, a strip-shaped bottom plate 8b is welded on the inclined plane, one end of the bottom plate 8b is in contact with the base 2, and the other end of the bottom plate 8b is tilted upwards and extends to the outside of the right side of the base 2.

The two ends of the bottom plate 8b are respectively provided with a reverse buckling through groove 8c, guide strips 8d axially distributed along the bottom plate 8b are arranged in the two through grooves 8c in a penetrating mode, the upper sides of the guide strips 8d are fixedly connected with the bottoms of the through grooves 8c, and a certain distance is reserved between the lower sides of the guide strips and the bottom plate 8 b.

The bottom plates 8b on the left side and the right side of the middle part of the guide strip 8d are respectively provided with a guide plate 8e, shaping blocks 8f are outwards symmetrically protruded on the side walls on the two sides of the guide strip 8d on one side of the guide plate 8e, and a third guide groove 8h distributed along the length direction of the base 2 is arranged on the base 2 at one end of the bottom plate 8 b.

The base 2 at one end of the third guide groove 8h is provided with first guide grooves 3 distributed along the width direction of the base 2, and one end of the third guide groove 8h is communicated with the first guide grooves 3. A first pushing component 4 is arranged on the base 2 at one end of the first guide groove 3.

The first pushing component 4 comprises a first cylinder support 4a connected to the thickness end face of the base 2 at one end of the first guide groove 3, and a first cylinder 4b outputting along the direction of the first guide groove 3 is arranged on the first cylinder support 4 a.

The output end of the first air cylinder 4b is connected with an L-shaped first pushing rod 4c, the first pushing rod 4c comprises a vertical section and a horizontal section, the vertical section is fixedly connected with the output end of the first air cylinder 4b, the horizontal section is positioned in the first guide groove 3, and the horizontal section is driven to slide back and forth in the first guide groove 3 through the expansion and contraction of the output end of the first air cylinder 4b.

A first limit bracket 4d is further arranged on the base 2 at one side of the first cylinder bracket 4a, and a first stop block 4e which is in limit fit with the vertical section of the pushing rod 4c is arranged on the first limit bracket 4 d. The base 2 is provided with second guide grooves 5 distributed along the length direction, and the other end of the first guide groove 3 is communicated with the second guide groove 5. A second pushing component 6 is arranged on the base 2 at one side of the feeding component 8.

The second pushing component 6 comprises a second cylinder bracket 6a connected to the base 2 at one end of the second guide groove 5, a second cylinder 6b fixedly connected to the second cylinder bracket 6a and outputting along the direction of the second guide groove 5, a second pushing rod 6c in an L shape connected to the output end of the second cylinder 6b, the second pushing rod 6c also comprises a vertical section and a horizontal section, the vertical section is connected with the output end of the second cylinder 6b, the horizontal section is located in the second guide groove 5, and the horizontal section is driven to slide back and forth in the second guide groove 5 by the expansion and contraction of the output end of the second cylinder 6 b.

A second limiting block 6d correspondingly matched with the output end of the second cylinder 6b is arranged on the second guide groove 5 on one side of the joint of the first guide groove 3 and the second guide groove 5 in a straddling way. The second guide groove 5 on the other side of the joint of the first guide groove 3 and the second guide groove 5 is provided with a component guide groove 9 in a crossing way, the pin guide groove 9 is of a through groove structure, and the groove bottom of the end part of the component guide groove 9 close to one side of the first guide groove 3 is provided with a convex dividing block 9a, so that the pin guide groove 9 at the end is divided into two small through grooves so as to correspond to two columns of pins on the component.

The base 2 on one side of the second guide groove 5 is provided with a support, the support is fixedly connected with a blowing pipe 11, the air outlet end of the blowing pipe 11 is positioned above the component guide groove 9 and opposite to the second guide groove 5, the axial direction of the blowing pipe 11 is opposite to the bottom surface of the second guide groove 5 to form an acute angle, one section of the blowing pipe 11 is communicated with an air source through the air pipe, and a control valve which is correspondingly matched is further arranged on the air pipe, so that the support air pipe, the control valve and the air source are not shown in the figure for convenience of view.

The second guide groove 5 is divided into a left part 5a and a right part 5b by taking a dividing block 9a of the device guide groove 9 as a dividing line, and the right part 5b is communicated with the first guide groove 3, and the bottom of the right part is communicated with the bottom of the first guide groove 3. The groove bottom of the left part 5a is slightly deeper than the groove bottom of the right part 5b, and the groove walls at the two sides of the left part 5a are also provided with steps 5c distributed along the axial direction.

A cutting unit 7 is provided on the top plate 1d on the left side of the component guide groove 9. The shaping and cutting assembly 7 comprises a top plate 1d of the frame 1, wherein vertically distributed air cylinders 7a are arranged on the top plate 1d, output shafts of the air cylinders 7a penetrate through the top plate 1d downwards, and movable plates 7c are connected to the lower ends of the output shafts of the air cylinders through connecting seats 7 b. The connecting seat 7b is connected with a cantilever 7k extending outwards, a top plate 1d above the cantilever 7k is provided with a guide sleeve 7z which is vertically distributed, a guide rod 7j is arranged in the guide sleeve 7z in a penetrating mode, and the lower end of the guide rod 7j is connected with the cantilever 7k in a matching mode.

An upper die holder 7d is connected to the bottom surface of the moving plate 7c, and a first punch head 7e, a second punch head 7f, and a cutting head 7h are sequentially connected to the upper die holder 7d in the axial direction of the second guide groove 5. A group of guide rods 7g are also arranged on the moving plate 7c on one side of the upper die holder 7d in a penetrating way, and buffer springs 7t are also arranged on the guide rods 7g between the moving plate 7c and the base 2 in a penetrating way. The punching end of the first punching head 7e is in a wedge shape which is gradually narrowed downwards, and the punching end of the second punching head 7f is in a horizontal plane.

A blanking hole 12 is arranged at the bottom of the left part 5a of the second guide groove 5 right below the cutting head 7h, the blanking hole 12 penetrates through the base 2 and the frame bottom plate 1a of the frame 1, and a receiving frame (not shown in the figure) distributed corresponding to the blanking hole 12 is arranged below the frame bottom plate 1a

A console 10 is arranged on one side of a frame bottom plate 1a of the frame 1, and the first air cylinder 4b, the second air cylinder 6b, the air cylinder 7a and the control valve form electric signal connection control coordination with the console 10 through cables which are shown in the figure.

The working process comprises the following steps:

firstly, the components 13 to be shaped are put into the feeding assembly 8 in the upward postures of the pins, the pins are distributed on two sides of the guide strip 8d, the components slide downwards under the action of gravity and then are contacted with the shaping block 8f, and the pins of the components 13 are opened to two sides under the action of the shaping block 8f, so that the shaping is completed once. If the component 13 cannot pass through the shaping block 8f under the use of its own weight, a worker manually pulls the component through the shaping block 8f to complete the first shaping.

The first shaped component 13 is drawn into the third guide groove 8h along the bottom plate 8b, the rear component 13 continuously advances under the pushing of the subsequent component 13 and then enters the first guide groove 3, the control console controls the output end of the first cylinder 4b to extend to push the component into the right part 5b of the second guide groove 5, and the control console controls the output end of the second cylinder 6b to push the component into the guide groove 9.

When the output end of the first cylinder 4b is retracted, the components in the third guide groove 8h continue to enter the first guide groove 3 under the pushing of the subsequent components 13, then are pushed into the right part 5b of the second guide groove 5, and are pushed into the guide groove 9 by the output end of the second cylinder 6b so as to push the previous components continuously forwards along the left part 5a of the second guide groove 5.

The components entering the left part 5a of the second guide groove 5 continuously move forward under the pushing of the subsequent components 13, and when the components pass under the first stamping head 7e, the pins of the components are opened at two further sides under the stamping shaping of the first stamping head 7e to finish secondary shaping. And then the pin of the component is formed into a step-shaped structure at the position of the pin close to the main body of the component 13 under the combined action of the step 5c and the second stamping head 7f under the stamping shaping of the second stamping head 7f after the component 13 is pushed to move below the second stamping head 7f, so that the three-time shaping is completed.

And then the component 13 subjected to three-time shaping enters the blanking hole 12 under the pushing of the subsequent component 13, redundant pins are punched under the action of the cutting head 7h, and the punched component 13 falls into the receiving frame from the blanking hole 12, so that the whole shaping process of shaping the inserted component into the mounted component is completed.

Claims (4)

1. The shaping device for shaping the inserted components into the mounted components comprises a frame (1), wherein a base (2) is arranged on the frame (1), and is characterized in that: the feeding device comprises a base (2), feeding components (8) which are obliquely distributed, a first guide groove (3) is formed in the base (2) on one side of the feeding components (8), a first pushing component (4) which is correspondingly matched with the first guide groove (3) is arranged on the base (2), a second guide groove (5) which is communicated with the first guide groove (3) is also formed in the base (2), a second pushing component (6) which is correspondingly matched with the second guide groove (5) is arranged on the base (2), a shaping cutting component (7) which is correspondingly matched with the second guide groove (5) is arranged on a frame above the second guide groove (5), and a console (10) which is in electric signal connection control fit with the first pushing component (4), the second pushing component (6) and the shaping cutting component (7) is also arranged on one side of the frame (1);

the feeding assembly (8) comprises a supporting seat (8 a) arranged on a base (2) at one side of the first guide groove (3), a bottom plate (8 b) is fixedly connected to the top end of the supporting seat (8 a), one end of the bottom plate (8 b) is contacted with the base (2), the other end of the bottom plate is tilted upwards, through grooves (8 c) are formed in the end parts at two ends of the bottom plate (8 b), guide strips (8 d) axially distributed along the bottom plate (8 b) are penetrated in the two through grooves (8 c), the upper sides of the guide strips (8 d) are fixedly connected with the bottoms of the through grooves (8 c), a certain distance is reserved between the lower sides of the guide strips and the bottom plate (8 b), a guide plate (8 e) is respectively arranged on the bottom plate (8 b) at the left side and the right side of the middle of the guide strip (8 d), shaping blocks (8 f) are outwards symmetrically protruded on the side walls at two sides of the guide plate (8 e), guide strips (8 h) at one end of the bottom plate (8 b) are arranged on the base (2) and are communicated with the first guide groove (3), and pins (8 h) are distributed on the two sides of the guide strips (8 h) to enable pins (13) to be spread upwards, so that the pins (13) are spread upwards, and the pins are spread upwards on the two sides of the guide elements (8 b;

the first pushing assembly (4) comprises a first air cylinder bracket (4 a) connected to the base (2) at one end of the first guide groove (3), a first air cylinder (4 b) outputting along the direction of the first guide groove (3) is arranged on the first air cylinder bracket (4 a), an L-shaped first pushing rod (4 c) is connected to the output end of the first air cylinder (4 b), the first pushing rod (4 c) comprises a vertical section and a horizontal section, the vertical section is connected with the output end of the first air cylinder (4 b), and the horizontal section is positioned in the first guide groove (3) and forms sliding fit with the first air cylinder; a first limit bracket (4 d) is further arranged on the base (2) at one side of the first cylinder bracket (4 a), and a first stop block (4 e) which is in limit fit with the vertical section of the first pushing rod (4 c) is arranged on the first limit bracket (4 d);

the second pushing assembly (6) comprises a second cylinder bracket (6 a) connected to the base (2) at one end of the second guide groove (5), a second cylinder (6 b) outputting along the direction of the second guide groove (5) is arranged on the second cylinder bracket (6 a), an L-shaped second pushing rod (6 c) is connected to the output end of the second cylinder (6 b), the second pushing rod (6 c) also comprises a vertical section and a horizontal section, the vertical section is connected with the output end of the second cylinder (6 b), the horizontal section is positioned in the second guide groove (5) to form sliding fit with the second guide groove, and a second limiting block (6 d) correspondingly matched with the output end of the second cylinder (6 b) is also arranged on the second guide groove (5) in a crossing manner;

the shaping and cutting assembly (7) comprises a vertically distributed air cylinder (7 a) arranged on the frame (1), a movable plate (7 c) is connected to an output shaft of the air cylinder through a connecting seat (7 b), an upper die holder (7 d) is connected to the bottom surface of the movable plate (7 c), a first punching head (7 e), a second punching head (7 f) and a cutting head (7 h) are sequentially connected to the upper die holder (7 d) along the axial direction of the second guide groove (5), a group of guide rods (7 g) are further arranged on the movable plate (7 c) on one side of the upper die holder (7 d) in a penetrating mode, and buffer springs are further sleeved on the guide rods (7 g) between the movable plate (7 c) and the base (2).

2. A shaping device for shaping a mounted component into a mounted component according to claim 1, wherein: the base (2) on one side of the second guide groove (5) is provided with a support, the support is connected with an air blowing pipe (11), the air outlet end of the air blowing pipe (11) is positioned on one side of the shaping and cutting assembly (7) and opposite to the second guide groove (5), the axial direction of the air blowing pipe (11) forms an acute angle with the bottom surface of the second guide groove (5), one end of the air blowing pipe (11) is communicated with an air source through the air pipe, a control valve which is correspondingly matched is further arranged on the air pipe, and the control valve is in electric signal connection control matching with a control console (10) through a lead.

3. A shaping device for shaping a mounted component into a mounted component according to claim 1, wherein: the connecting seat (7 b) is connected with a cantilever (7 k) which extends outwards, the frame (1) above the cantilever (7 k) is penetrated with a guide rod (7 j), and the lower end of the guide rod (7 j) is connected with the cantilever (7 k).

4. A reshaping apparatus for reshaping a mounted component into a mounted component as in claim 2 or 3, wherein: the blanking hole (12) is formed in the bottom of one end portion of the second guide groove (5), the blanking hole (12) penetrates through the base (2) and a frame bottom plate of the frame (1), and a receiving frame which is distributed corresponding to the blanking hole (12) is arranged below the frame bottom plate of the frame (1).