CN116511348B

CN116511348B - Continuous extrusion die for automobile camera

Info

Publication number: CN116511348B
Application number: CN202310529145.XA
Authority: CN
Inventors: 高武龙; 刘秋华; 陈前勇; 陈志远; 赵腾飞; 陈远
Original assignee: Shenzhen City Xin Maoxin Industrial Co ltd
Current assignee: Shenzhen City Xin Maoxin Industrial Co ltd
Priority date: 2023-05-11
Filing date: 2023-05-11
Publication date: 2024-05-14
Anticipated expiration: 2043-05-11
Also published as: CN116511348A

Abstract

The invention belongs to the technical field of camera processing, and relates to a continuous extrusion die for an automobile camera, which comprises an upper die and a lower die, wherein a conveying support is arranged on the lower die, a conveying sliding rail is arranged on the conveying support, a lifting multi-section electric push rod is arranged on a conveying sliding block of the conveying sliding rail, a transverse multi-section electric push rod is arranged at the output end of the lifting multi-section electric push rod, a material taking strip is arranged at the output end of the transverse multi-section electric push rod, five material taking columns are sequentially arranged on the material taking strip and are matched with a coarse extrusion module, a fine extrusion module, a punching module, a shaping module and a rotary-cut module, material taking seats are arranged on the material taking columns, material taking plates are circumferentially arranged on the material taking seats, material taking bags are arranged on the outer sides of the material taking plates, and bag liquid is arranged inside the material taking bags. The invention improves the processing efficiency and saves the cost of machines and personnel through automatic continuous processing, can be adapted to raw materials with different specifications, and can also protect the surface of the raw materials from clamping damage.

Description

Continuous extrusion die for automobile camera

Technical Field

The invention belongs to the technical field of camera processing, and particularly relates to a continuous extrusion die for an automobile camera.

Background

Automobile autopilot is vigorously developed, wherein automobile camera laser radar research is used as auxiliary reference data of autopilot, and plays an important role in environmental perception and positioning in autopilot, so that requirements of cameras are also higher and higher, the production processes of face shells, bottom shells and shells of radar cameras in the market are mainly die-casting molding and full CNC processing, the die-casting molding compactness is not enough, sand holes are easily formed, and the full CNC processing cost is high. At present, the development technology of market dies is mature, along with the continuous increase of the die hardware industry, the cost is continuously increased, the market demand is excessively saturated, the price of the hardware processing industry is transparent, the traditional die structure has some defects, for products with high precision and complex structures, the extrusion process is more, and meanwhile, the required machines and staff are more, so that the processing cost is high.

Disclosure of Invention

The invention aims to provide a continuous extrusion die for an automobile camera, which solves the technical problem of high processing cost caused by a plurality of extrusion procedures in the prior art.

In order to achieve the above purpose, the invention adopts the following technical scheme:

The invention provides an automobile camera continuous extrusion die which comprises an upper die and a lower die, wherein a coarse extrusion module, a fine extrusion module, a punching module, a shaping module and a rotary cutting module are sequentially arranged between the upper die and the lower die, a conveying support is arranged on the lower die, a conveying sliding rail is arranged on the conveying support, a lifting multi-section electric push rod is arranged on a conveying sliding block of the conveying sliding rail, a transverse multi-section electric push rod is arranged at the output end of the lifting multi-section electric push rod, a material taking strip is arranged at the output end of the transverse multi-section electric push rod, five material taking columns are sequentially arranged on the material taking strip, the five material taking columns are matched with the coarse extrusion module, the fine extrusion module, the punching module, the shaping module and the rotary cutting module, material taking seats are arranged on the material taking columns, a circumferential array is provided with material taking plates, material taking bags are arranged on the outer sides of the material taking plates, and bag liquid bags are arranged inside the material taking bags.

Preferably, the bottom of getting material seat is equipped with the connecting pipe, the bottom of connecting pipe is equipped with the backup pad, get material seat with the outside of backup pad all is circumference array and is equipped with the spread groove, the inside slip of spread groove is equipped with the connecting rod, the connecting rod is in the outside port of spread groove with get the inboard of material board and be connected, the connecting rod is in be equipped with the connecting plate on the inside port of spread groove, the connecting plate with be equipped with connecting spring between the inner wall of spread groove.

Preferably, the inside of getting material seat is equipped with the inner chamber, the inside of inner chamber is equipped with the motor, the output of motor extends to the inside of connecting pipe, the output of motor is in be equipped with the lead screw on the inside port of connecting pipe, the bottom rotation of lead screw is located the top of backup pad, be the symmetry on the connecting pipe and be equipped with two spacing holes, be the symmetry on the lead screw nut of lead screw and be equipped with two stoppers, the stopper slip peg graft in the inside in spacing hole, the slip cap is equipped with the drive ring on the connecting pipe, the inboard of drive ring with the stopper is connected, the inboard of getting material board is equipped with the drive piece, be equipped with the drive inclined plane on the drive piece, the drive inclined plane is located the below of drive ring.

Preferably, the material taking plate is made of copper, the material taking bag comprises an inner pad and an outer film, the inner pad is made of hard rubber, and the outer film is made of soft rubber.

Preferably, the capsule liquid is a cooling liquid.

Preferably, the inner pad is adhered to the outer side of the material taking plate.

Preferably, the inner pad is provided with a connecting nozzle, the material taking plate is provided with a detecting pipe, the detecting pipe is provided with a detecting nozzle, the detecting nozzle is communicated with the connecting nozzle, the detecting pipe is adjacent to the inner wall of one side of the detecting nozzle and is provided with a bearing plate in a sliding manner, the bearing plate is opposite to the outer wall of one side of the detecting nozzle and is provided with a bearing spring, the other side of the bearing spring is provided with a pressure plate, and the pressure plate is arranged on the inner wall of one side of the detecting nozzle opposite to the detecting pipe.

Preferably, the inner pad is provided with a plurality of copper columns, and the copper columns are attached to the outer side of the material taking plate.

Compared with the prior art, the invention has the beneficial effects that:

According to the continuous extrusion die for the automobile camera, the five material taking columns on the material taking bar can drive the material taking seat to sequentially move the raw materials processed at the positions of the coarse extrusion module, the fine extrusion module, the punching module, the shaping module and the rotary cutting module to the next station through the mutual matching of the conveying sliding rail, the lifting multi-section electric push rod and the transverse multi-section electric push rod on the conveying support, so that the automatic continuous processing effect is realized, the processing efficiency is improved, the machine cost and the personnel cost are saved, meanwhile, the raw materials are clamped through the material taking bag, the continuous extrusion die can be suitable for raw materials with different specifications, and the stress area of the raw materials can be increased as much as possible through deformation of the outer film when the outer film is abutted against the inner side of the raw materials, so that the stress of the raw materials is uniform, the stress born by contact points is reduced, and the surface of the raw materials is protected from clamping damage.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are needed in the description of the embodiments or the prior art will be briefly described, and it is obvious that the drawings in the description below are some embodiments of the present invention, and other drawings can be obtained according to the drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of a three-dimensional structure of a continuous extrusion die for an automobile camera;

FIG. 2 is a schematic perspective view of a conveying support, a conveying sliding rail, a lifting multi-section electric push rod, a transverse multi-section electric push rod, a material taking bar, a material taking column and a material taking seat;

FIG. 3 is a schematic perspective view of a take-out seat, take-out plate and take-out bladder according to the present invention;

FIG. 4 is a schematic cross-sectional view of a take-out seat, take-out plate and take-out bladder of the present invention;

FIG. 5 is an enlarged schematic view of the structure of FIG. 4A according to the present invention;

fig. 6 is an enlarged view of the structure of fig. 4B according to the present invention.

In the figure: 1. an upper die; 11. a lower die; 2. a conveying support; 21. conveying a sliding rail; 22. lifting the multisection electric push rod; 23. transverse multisection electric push rod; 24. a material taking strip; 25. a material taking column; 3. a material taking seat; 31. a connecting pipe; 32. a support plate; 33. a connecting rod; 34. a connecting plate; 35. a connecting spring; 36. a motor; 37. a screw rod; 371. a limiting block; 38. a drive ring; 39. a driving block; 4. a material taking plate; 41. a detection tube; 42. detecting a mouth; 43. a pressure bearing plate; 44. a pressure-bearing spring; 45. a pressure plate; 5. a material taking bag; 51. an inner pad; 52. an outer membrane; 53. a connecting nozzle; 54. copper columns; 6. and (3) a cyst fluid.

Detailed Description

The following description of the embodiments of the present invention will be made apparent and fully in view of the accompanying drawings, in which some, but not all embodiments of the invention are shown.

The components of the embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the invention, as presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention.

All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In the description of the present invention, it should be noted that the directions or positional relationships indicated by the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

Referring to fig. 1 to 6, the present invention provides a continuous extrusion die for an automobile camera, including an upper die 1 and a lower die 11, a rough extrusion module, a fine extrusion module, a punching module, a shaping module and a rotary cutting module are sequentially arranged between the upper die 1 and the lower die 11, a conveying support 2 is arranged on the lower die 11, a conveying sliding rail 21 is arranged on the conveying support 2, a lifting multi-section electric push rod 22 is arranged on a conveying sliding block of the conveying sliding rail 21, a transverse multi-section electric push rod 23 is arranged at an output end of the lifting multi-section electric push rod 22, a material taking strip 24 is arranged at an output end of the transverse multi-section electric push rod 23, five material taking columns 25 are sequentially arranged on the material taking strip 24, the five material taking columns 25 are matched with the rough extrusion module, the fine extrusion module, the punching module, the shaping module and the rotary cutting module, a material taking seat 3 is arranged on the material taking column 25, a circumference array is arranged on the material taking plate 4, a material taking bag 5 is arranged on an outer side of the material taking plate 4, and a bag liquid 6 is arranged inside the bag 5.

When the raw materials are processed by the coarse extrusion module, the fine extrusion module, the punching module, the shaping module and the rotary cutting module between the upper die 1 and the lower die 11, through the mutual matching of the conveying sliding rail 21, the lifting multi-section electric push rod 22 and the transverse multi-section electric push rod 23 on the conveying support 2, the five material taking columns 25 on the material taking strip 24 drive the material taking seat 3 to sequentially move the raw materials processed by the coarse extrusion module, the fine extrusion module, the punching module, the shaping module and the rotary cutting module to the next station, so that the automatic continuous processing effect is realized, the processing efficiency is improved, and the machine and personnel cost is saved.

Specifically, firstly, the material taking seat 3 is driven to move to a preset position by the conveying sliding rail 21, then the material taking seat 3 is driven to extend between the upper die 1 and the lower die 11 by the transverse multi-section electric push rod 23, when the material taking seat 3 extends to the position right above the rough extrusion module, the fine extrusion module, the punching module, the shaping module and the rotary cutting module, the material taking seat 3 can be driven to descend to the positions of the rough extrusion module, the fine extrusion module, the punching module, the shaping module and the rotary cutting module by the lifting multi-section electric push rod 22, then the material taking bag 5 on the material taking plate 4 is driven by the material taking seat 3 to clamp the processed raw materials, then the raw materials clamped by the material taking seat 3 are driven to ascend to the position right above the rough extrusion module, the fine extrusion module, the punching module, the shaping module and the rotary cutting module by the lifting multi-section electric push rod 22, when the raw materials clamped by the material taking seat 3 are completely separated from the rough extrusion module, the fine extrusion module, the punching module, the shaping module and the rotary cutting module, the raw materials clamped by the material taking seat 3 can be driven to move to the next station by the conveying slide rail 21, at the moment, the raw materials to be processed are supplemented to the rough extrusion module by the material supplementing device, meanwhile, finished products sequentially processed by the rough extrusion module, the fine extrusion module, the punching module, the shaping module and the rotary cutting module are moved to the position right above a finished product conveying belt, then the material taking seat 3 is driven to descend to the position of the fine extrusion module, the punching module, the shaping module, the rotary cutting module and the finished product conveying belt by the lifting multi-section electric push rod 22, then the raw materials are loosened by the material taking seat 3 by the material taking bag 5 on the material taking plate 4, then the material taking seat 3 is driven to ascend to the position right above the fine extrusion module, the punching module, the shaping module, the rotary cutting module and the finished product conveying belt by the lifting multi-section electric push rod 22, at this time, the material taking seat 3 is driven to retract to the outer sides of the upper die 1 and the lower die 11 by the transverse multi-section electric push rod 23, and then the material taking seat 3 is driven to move to a preset position by the conveying slide rail 21, so that the effect of automatic continuous processing is realized.

The bottom of the material taking seat 3 is provided with a connecting pipe 31, the bottom of the connecting pipe 31 is provided with a supporting plate 32, the outer sides of the material taking seat 3 and the supporting plate 32 are respectively provided with a connecting groove in a circumferential array, the inside of the connecting grooves is slidably provided with a connecting rod 33, the port of the connecting rod 33 outside the connecting grooves is connected with the inner side of the material taking plate 4, the port of the connecting rod 33 inside the connecting grooves is provided with a connecting plate 34, a connecting spring 35 is arranged between the connecting plate 34 and the inner wall of the connecting grooves, the inside of the material taking seat 3 is provided with an inner cavity, the inside of the inner cavity is provided with a motor 36, the output end of the motor 36 extends to the inside of the connecting pipe 31, the output end of the motor 36 is provided with a screw rod 37 on the port inside the connecting pipe 31, the bottom end of the screw rod 37 is rotationally arranged at the top of the supporting plate 32, two limiting holes are symmetrically arranged on the connecting pipe 31, two limiting blocks 371 are symmetrically arranged on screw nuts of the screw rod 37, the limiting block 371 is slidably inserted into the limiting hole, the driving ring 38 is slidably sleeved on the connecting pipe 31, the inner side of the driving ring 38 is connected with the limiting block 371, the driving block 39 is arranged on the inner side of the material taking plate 4, a driving inclined surface is arranged on the driving block 39, the driving inclined surface is positioned below the driving ring 38, when the motor 36 drives the screw rod 37 to rotate positively, the screw rod nut on the screw rod 37 drives the driving ring 38 connected with the two limiting blocks 371 to descend, when the driving ring 38 abuts against the driving inclined surface of the driving block 39 to descend, the driving ring 38 drives the driving block 39 to move outwards, thereby driving the material taking plate 4 on the driving block 39 to move outwards, when the material taking plate 4 moves outwards, the connecting plate 34 on the connecting rod 33 is driven to apply acting force to the connecting spring 35 to deform, when the material taking bag 5 on the material taking plate 4 abuts against the inner side of the raw material, the raw material can be clamped, when the motor 36 drives the screw rod 37 to rotate reversely, the screw rod nut on the screw rod 37 drives the driving ring 38 connected with the two limiting blocks 371 to rise, when the driving ring 38 rises, the connecting plate 34 drives the material taking plate 4 on the connecting rod 33 to move inwards under the action force of the restoring deformation of the connecting spring 35, so that the driving block 39 on the material taking plate 4 is driven to move inwards, meanwhile, the driving inclined surface of the driving block 39 is abutted to the driving ring 38, and when the material taking bag 5 on the material taking plate 4 is separated from the inner side of the raw material, the raw material can be loosened.

The inner pad 51 is provided with the connecting nozzle 53, the material taking plate 4 is provided with the detecting tube 41, the detecting tube 41 is provided with the detecting nozzle 42, the detecting nozzle 42 is communicated with the connecting nozzle 53, the inner wall of the detecting tube 41 adjacent to one side of the detecting nozzle 42 is slidingly provided with the pressure bearing plate 43, the outer wall of the pressure bearing plate 43 opposite to one side of the detecting nozzle 42 is provided with the pressure bearing spring 44, the other side of the pressure bearing spring 44 is provided with the pressure plate 45, the pressure plate 45 is arranged on the inner wall of the detecting tube 41 opposite to one side of the detecting nozzle 42, therefore, when the material taking bag 5 on the material taking plate 4 is abutted against the inner side of the raw material, bag liquid 6 in the material taking bag 5 flows into the detecting tube 41 through the connecting nozzle 53 and the detecting nozzle 42 under the extrusion action of the material taking plate 4 and the raw material, at this moment, the bag liquid 6 can drive the pressure bearing plate 43 to apply acting force to the pressure plate 45 connected with the pressure bearing spring 44, when the pressure plate 45 detects that the pressure value reaches a preset value, the motor 36 can be controlled to stop rotating, and when the pressure value is not detected by the pressure plate 45, the accuracy of the material taking bag 5 on the material taking plate 4 is proved to be separated from the inner side of the raw material, thereby ensuring that the raw material is clamped and the raw material is released.

The material taking bag 5 comprises an inner pad 51 and an outer film 52, the inner pad 51 is adhered to the outer side of the material taking plate 4, the inner pad 51 is made of hard rubber, the inner pad 51 is adhered to the outer side of the material taking plate 4 conveniently, the outer film 52 is made of soft rubber, and the outer film 52 is made of stretch-proof soft rubber, so that when the material taking bag 5 is abutted to the inner side of a raw material, the bag liquid 6 in the material taking bag 5 is guaranteed to conduct extrusion acting force to the pressure plate 45, and the accuracy of clamping the raw material and loosening the raw material is further guaranteed.

Further, the material is clamped through the material taking bag 5, so that the material taking bag can be adapted to raw materials with different specifications, and when the outer film 52 is abutted against the inner side of the raw materials, the stress area of the raw materials can be increased as much as possible through deformation of the outer film 52, so that the raw materials are stressed uniformly, the force born by contact points is reduced, and the surface of the raw materials is protected from clamping damage.

The material taking plate 4 is made of copper, the bag liquid 6 is cooling liquid, a plurality of copper columns 54 are arranged on the inner pad 51, the copper columns 54 are attached to the outer side of the material taking plate 4, so that when the outer film 52 is abutted to the inner side of the raw material, heat carried by the raw material can be conducted to the material taking plate 4 through the bag liquid 6 to be emitted, the raw material can be shaped more quickly, and the surface of the raw material is further protected from clamping damage.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present invention, and not for limiting the same; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some or all of the technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the invention.

Claims

1. The utility model provides a car camera continuous extrusion mould, includes mould (1) and bed die (11), its characterized in that: the automatic feeding device comprises an upper die (1) and a lower die (11), wherein a coarse extrusion module, a fine extrusion module, a punching module, a shaping module and a rotary cutting module are sequentially arranged between the upper die and the lower die (11), a conveying support (2) is arranged on the lower die (11), a conveying sliding rail (21) is arranged on the conveying support (2), a lifting multi-section electric push rod (22) is arranged on a conveying sliding block of the conveying sliding rail (21), a transverse multi-section electric push rod (23) is arranged at the output end of the lifting multi-section electric push rod (22), a material taking strip (24) is arranged at the output end of the transverse multi-section electric push rod (23), five material taking columns (25) are sequentially arranged on the material taking strip (24), the five material taking columns (25) are matched with the coarse extrusion module, the fine extrusion module, the punching module and the shaping module, the rotary cutting module, a material taking seat (3) is arranged on the material taking column (25), a circumference array is provided with a plate (4), and the outer side of the lifting multi-section electric push rod (22) is provided with a material taking bag (5), and the material taking bag (5) is arranged in the material taking seat (3).

The bottom of the material taking seat (3) is provided with a connecting pipe (31), the bottom of the connecting pipe (31) is provided with a supporting plate (32), the material taking seat (3) and the outer side of the supporting plate (32) are all provided with connecting grooves in a circumferential array, the inside of each connecting groove is slidably provided with a connecting rod (33), the connecting rods (33) are connected with the inner side of the material taking plate (4) at the outer ports of the connecting grooves, the connecting rods (33) are provided with connecting plates (34) at the inner ports of the connecting grooves, and connecting springs (35) are arranged between the connecting plates (34) and the inner walls of the connecting grooves;

The inside of getting material seat (3) is equipped with the inner chamber, the inside of inner chamber is equipped with motor (36), the output of motor (36) extends to the inside of connecting pipe (31), the output of motor (36) is in be equipped with lead screw (37) on the inside port of connecting pipe (31), the bottom rotation of lead screw (37) is located the top of backup pad (32), be the symmetry on connecting pipe (31) and be equipped with two spacing holes, be the symmetry on the lead screw nut of lead screw (37) and be equipped with two stopper (371), stopper (371) sliding grafting in the inside of spacing hole, the slip cap is equipped with drive ring (38) on connecting pipe (31), the inboard of drive ring (38) with stopper (371) are connected, the inboard of getting material board (4) is equipped with drive piece (39), be equipped with the drive inclined plane on drive piece (39), the drive inclined plane is located the below of drive ring (38).

2. The continuous extrusion die for automobile cameras according to claim 1, wherein: the material taking plate (4) is made of copper, the material taking bag (5) comprises an inner pad (51) and an outer film (52), the inner pad (51) is made of hard rubber, and the outer film (52) is made of soft rubber.

3. The continuous extrusion die for automobile cameras according to claim 1, wherein: the bag liquid (6) is cooling liquid.

4. The continuous extrusion die for automobile cameras according to claim 2, wherein: the inner pad (51) is adhered to the outer side of the material taking plate (4).

5. The continuous extrusion die for automobile cameras according to claim 2, wherein: be equipped with connecting mouth (53) on inner pad (51), be equipped with on getting material board (4) and detect pipe (41), be equipped with on detecting pipe (41) and detect mouth (42), detect mouth (42) with connect mouth (53) and be linked together, detect pipe (41) adjacent on the inner wall of detecting mouth (42) one side and slide and be equipped with bearing plate (43), bearing plate (43) back to each other in be equipped with pressure-bearing spring (44) on the outer wall of detecting mouth (42) one side, the opposite side of pressure-bearing spring (44) is equipped with pressure plate (45), pressure plate (45) are located detect pipe (41) back to each other in on the inner wall of detecting mouth (42) one side.

6. The continuous extrusion die for automobile cameras according to claim 2, wherein: the inner pad (51) is provided with a plurality of copper columns (54), and the copper columns (54) are attached to the outer side of the material taking plate (4).