CN115229100A

CN115229100A - Alloy forming automatic production equipment

Info

Publication number: CN115229100A
Application number: CN202210749439.9A
Authority: CN
Inventors: 徐士舟
Original assignee: Huaian Jianghuai Burden Co ltd
Current assignee: Huaian Jianghuai Burden Co ltd
Priority date: 2022-06-29
Filing date: 2022-06-29
Publication date: 2022-10-25

Abstract

The invention discloses an automatic alloy molding production device which comprises a shell, wherein a molding cavity is arranged in the shell, a female die is arranged on one side in the molding cavity, and a male die is arranged on the other side in the molding cavity; the die is characterized by further comprising a compression bar, wherein the compression bar is fixedly arranged on one side of the male die, racks are fixedly arranged at the front end and the rear end of the compression bar, driving motors are fixedly arranged at the front end and the rear end of the transmission cavity, driving gears are arranged in the middle of output shafts of the driving motors, the compression bar is positioned between the driving gears, and the driving gears are meshed with the racks; the ejection device comprises an ejection block, a threaded telescopic column, a threaded sleeve and a shell, wherein the ejection block is arranged on one side of a female die, the threaded telescopic column is arranged on one side of the ejection block, the ejection block is connected with one end of the threaded telescopic column through a bearing, the threaded sleeve is arranged outside the threaded telescopic column, and the outer part of the threaded sleeve is connected with the shell through the bearing.

Description

Alloy forming automatic production equipment

Technical Field

The invention relates to the technical field of alloy forming equipment, in particular to automatic alloy forming production equipment.

Background

With the continuous development of alloy production technology, higher requirements on the forming quality of alloy are met, and meanwhile, the processing efficiency of alloy forming also directly influences the production level of alloy products.

For example chinese granted patent of No. CN210358750U "stamping forming equipment for aluminum alloy production," including base and punching press board, the punching press board level is located the base top, the equal fixedly connected with limit baffle in base top both sides, the base top installs the die board between two limit baffle, the equal fixedly connected with first screw rod in die board bottom both sides, first screw rod bottom runs through base threaded connection and has first mounting nut, the link bottom is installed with die board matched with die board, the equal fixedly connected with second screw rod in die board top both sides, second screw rod top runs through link threaded connection and has second mounting nut. The template is convenient for change, and the shaping is effectual, and the shaping time is short, improves work efficiency.

Although the prior art can realize flexible forming of alloy materials, the forming efficiency is low, and continuous forming processing of the alloy materials cannot be realized, so that the prior requirements are not met, and accordingly, an automatic alloy forming production device is provided.

Disclosure of Invention

The invention aims to provide alloy forming automatic production equipment to solve the problem that the continuous production efficiency of the alloy forming equipment provided by the background art is low.

In order to achieve the purpose, the invention provides the following technical scheme: the automatic alloy forming production equipment comprises a shell, wherein a forming cavity is arranged in the shell, a female die is arranged on one side in the forming cavity, the female die and the shell are fixed through bolts, and a male die is arranged on the other side in the forming cavity;

the die is characterized by further comprising a compression bar which is fixedly arranged on one side of the male die, racks are fixedly arranged at the front end and the rear end of the compression bar, a transmission cavity is arranged on one side inside the shell, driving motors are fixedly arranged at the front end and the rear end of the transmission cavity, driving gears are arranged in the middle of output shafts of the driving motors, the compression bar is positioned between the driving gears, and the driving gears are meshed with the racks;

the ejection block is arranged on one side of the female die, the threaded telescopic column is installed on one side of the ejection block, the ejection block is connected with one end of the threaded telescopic column through a bearing, the threaded sleeve is installed outside the threaded telescopic column, and the outer portion of the threaded sleeve is connected with the shell through the bearing.

Preferably, one of them the front end fixed mounting of driving motor output shaft has fifth bevel gear, one side of fifth bevel gear upper end is provided with first transfer line, the both ends of first transfer line are all fixed and are provided with first bevel gear, and the first bevel gear that is located first transfer line one side is connected with the meshing of fifth bevel gear, the second transfer line is installed to one side of first transfer line rear end, the both ends of second transfer line are all fixed and are provided with second bevel gear, and the second bevel gear that is located second transfer line one end is connected with the meshing of the first bevel gear of the first transfer line other end, the rear end of screw thread flexible post is provided with the third transfer line, the both ends of third transfer line are all fixed and are provided with third bevel gear, and the third bevel gear and the meshing of third transfer line one end are connected.

Preferably, one end of the threaded sleeve is fixedly provided with a sixth bevel gear, and the sixth bevel gear is in meshed connection with a third bevel gear at the other end of the third transmission rod.

Preferably, the internally mounted of flexible post of screw thread has spacing post, and the one end and the casing welded fastening of spacing post, the outside of spacing post is provided with four lugs that are annular equidistance and distribute, and lug and the inside cell body sliding connection of flexible post of screw thread.

Preferably, an alloy material guide device is arranged on the other side of the female die, material conveying mechanisms are arranged on two sides of the middle position of the alloy material guide device, and an empty groove is formed below the rear end of the alloy material guide device.

Preferably, the inside of defeated material mechanism is provided with a plurality of gyro wheels that distribute in proper order equidistance, accessible belt drive between the connecting axle of gyro wheel, mountable motor simultaneously on the connecting axle of outermost gyro wheel, the synchronous rotation of drive gyro wheel realizes the removal to the alloy material.

Preferably, an alloy feeding cavity is arranged above the forming cavity, a top plate is arranged inside the alloy feeding cavity and is connected with the alloy feeding cavity in a sliding mode, a spring is fixedly arranged between one side of the top plate and the alloy feeding cavity, and alloy materials are placed on the other side of the top plate.

Preferably, a sixth bevel gear is mounted on an output shaft of the other driving motor, a fourth transmission rod is mounted at the upper end of the sixth bevel gear, the fourth transmission rod and the sixth bevel gear are meshed through the fourth bevel gear, one end of the fourth transmission rod extends to the outside of the shell, and a protection rod is fixedly arranged at one end, located outside the shell, of the fourth transmission rod.

Preferably, the bottom of the shell is provided with a conveying belt.

The front end of the shell is provided with an observation window.

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

1. the invention realizes continuous molding processing of alloy materials by adopting linkage matching of alloy extrusion molding, discharging and feeding, when a male die is positioned at one molding side, a top block is close to a hollow groove of an alloy guide device, a drive gear on an output shaft of a drive motor drives a male die to move towards a female die under the matching of a pressure rod and a rack, the alloy materials positioned in the hollow groove are molded, in the moving process of the male die, a fifth bevel gear at one end of an output shaft of the drive motor drives a first bevel gear provided with a first drive rod to rotate under the meshing action, the first bevel gear at the other end of the first drive rod drives a second bevel gear provided with a second drive rod to rotate under the meshing action, similarly, the second drive rod drives a thread telescopic column to rotate through a third drive rod, a thread sleeve is connected with a shell through a bearing, the thread sleeve is in thread fit with the thread telescopic column, a limit column is arranged at the lower end of the thread telescopic column, a protruding structure outside the limit column can enable the thread telescopic column to be incapable of rotating, so that the female die can gradually shrink in the process of gradually separating the male die from the female die, the female die can be separated from the alloy materials, and the top block can be separated from the female die in the forming process of the male die, and the female die, the alloy materials, and the alloy materials can be separated from the female die, and the top block can be separated from the female die. And the linkage structure is stable, and the condition that the ejector block conflicts with the male die can not occur.

2. According to the invention, the alloy guide device is fixedly arranged on one side of the female die, after a synthetic material is formed, the material in the alloy feeding cavity can be pushed to the upper end of the alloy guide device under the action of the spring and the top plate, the roller in the feeding mechanism can synchronously rotate through the matching of the motor and the belt, so that the alloy raw material above the inner part can be conveyed downwards until the alloy material is contacted with the bottom of the alloy guide device, and the alloy material can enter the female die for forming through the empty groove under the action of the male die.

3. According to the invention, the protection rod is arranged on one side of the front end of the shell, the protection rod is linked with the male die and the ejector block, the male die moves towards the female die, and simultaneously, the output shaft of the other driving motor drives the fourth bevel gear provided with the fourth transmission rod to rotate, so that the protection rod swings at the front end of the shell, and the protection rod is reset due to the reverse rotation of the driving motor when the male die is separated.

Drawings

FIG. 1 is a top view of the internal structure of an alloy molded front housing of the present invention;

FIG. 2 is a top view of the internal structure of the shell after the alloy of the present invention is formed;

FIG. 3 is an inside elevational view of the housing of the present invention;

FIG. 4 is a perspective view of an alloy guiding device according to the present invention;

FIG. 5 is an enlarged view of the area A of FIG. 1 in accordance with the present invention;

fig. 6 is a partially enlarged view of the area B in fig. 1 according to the present invention.

In the figure: 1. a housing; 2. a molding cavity; 3. a female die; 4. a male die; 5. a transmission cavity; 6. a pressure lever; 7. a rack; 9. a drive motor; 10. a first drive lever; 11. a first bevel gear; 12. a second transmission rod; 13. a second bevel gear; 14. a third transmission rod; 15. a third bevel gear; 16. a threaded telescopic column; 17. a limiting column; 18. a top block; 19. an alloy material guide device; 20. an observation window; 21. a conveyor belt; 22. a fourth transmission rod; 23. a fourth bevel gear; 24. a guard bar; 25. an alloy feeding cavity; 26. a top plate; 27. a spring; 28. a material conveying mechanism; 29. a roller; 30. an empty groove; 31. a fifth bevel gear; 32. a threaded sleeve; 33. a sixth bevel gear; 34. the gears are driven.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1-6, an embodiment of the present invention is shown: the automatic alloy forming production equipment comprises a shell 1, wherein a forming cavity 2 is arranged inside the shell 1, a female die 3 is arranged on one side inside the forming cavity 2, the female die 3 and the shell 1 are fixed through bolts, and a male die 4 is arranged on the other side inside the forming cavity 2;

the die is characterized by further comprising a compression bar 6, wherein the compression bar 6 is fixedly arranged on one side of the male die 4, racks 7 are fixedly arranged at the front end and the rear end of the compression bar 6, a transmission cavity 5 is arranged on one side inside the shell 1, driving motors 9 are fixedly arranged at the front end and the rear end of the transmission cavity 5, a driving gear 34 is arranged in the middle of an output shaft of each driving motor 9, the compression bar 6 is positioned between the driving gears 34, and the driving gears 34 are meshed with the racks 7;

the ejector block 18 is arranged on one side of the female die 3, the threaded telescopic column 16 is installed on one side of the ejector block 18, the ejector block 18 is connected with one end of the threaded telescopic column 16 through a bearing, the threaded sleeve 32 is installed on the outer portion of the threaded telescopic column 16, and the outer portion of the threaded sleeve 32 is connected with the shell 1 through a bearing.

Referring to the drawing, a fifth bevel gear 31 is fixedly mounted at the front end of an output shaft of one of the driving motors 9, a first transmission rod 10 is disposed at one side of the upper end of the fifth bevel gear 31, first bevel gears 11 are fixedly disposed at both ends of the first transmission rod 10, the first bevel gear 11 located at one side of the first transmission rod 10 is in meshed connection with the fifth bevel gear 31, a second transmission rod 12 is mounted at one side of the rear end of the first transmission rod 10, second bevel gears 13 are fixedly disposed at both ends of the second transmission rod 12, the second bevel gear 13 located at one end of the second transmission rod 12 is in meshed connection with the first bevel gear 11 at the other end of the first transmission rod 10, a third transmission rod 14 is disposed at the rear end of the threaded telescopic column 16, third bevel gears 15 are fixedly disposed at both ends of the third transmission rod 14, and the third bevel gear 15 at one end of the third transmission rod 14 is in meshed connection with the second bevel gear 13, so that separation of alloy materials can be automatically achieved, and the linkage structure is stable, and collision between the top block 18 and the male mold 4 can be avoided.

Referring to fig. 1, 2 and 4, a sixth bevel gear 33 is fixedly disposed at one end of the threaded sleeve 32, and the sixth bevel gear 33 is engaged with the third bevel gear 15 at the other end of the third transmission rod 14, so that the top block 18 can be gradually contracted under the rotation of the third bevel gear 15.

Referring to fig. 1, 2, 3 and 5, a limiting column 17 is installed inside the threaded telescopic column 16, one end of the limiting column 17 is welded and fixed to the housing 1, four protruding blocks distributed in an annular and equidistant manner are arranged outside the limiting column 17, the protruding blocks are connected with a groove body inside the threaded telescopic column 16 in a sliding manner, and the threaded telescopic column 16 cannot rotate due to a protruding structure outside the limiting column 17, so that telescopic stability is ensured.

Referring to fig. 1-4, an alloy guiding device 19 is disposed on the other side of the female mold 3, material conveying mechanisms 28 are disposed on both sides of the middle of the alloy guiding device 19, and a hollow groove 30 is disposed below the rear end of the alloy guiding device 19, so that not only can automatic continuous feeding of alloy material be realized, but also the alloy material can be positioned by the hollow groove 30, and accuracy of a molding process is ensured.

Referring to fig. 4, a plurality of rollers 29 are arranged inside the feeding mechanism 28 and are distributed in sequence at equal intervals, connecting shafts of the rollers 29 can be driven by a belt, a motor can be mounted on the connecting shaft of the outermost roller 29, and the rollers 29 are driven to rotate synchronously to move the alloy material.

Referring to fig. 3, an alloy feeding cavity 25 is disposed above the molding cavity 2, a top plate 26 is disposed inside the alloy feeding cavity 25, the top plate 26 is slidably connected to the alloy feeding cavity 25, a spring 27 is fixedly disposed between one side of the top plate 26 and the alloy feeding cavity 25, and the alloy material is placed on the other side of the top plate 26 and can be pushed to the upper end of the alloy material guiding device under the action of the spring 27 and the top plate 26.

Referring to fig. 1 and 2, a sixth bevel gear is mounted on an output shaft of another driving motor 9, a fourth transmission rod 22 is mounted at the upper end of the sixth bevel gear, the fourth transmission rod 22 is meshed with the sixth bevel gear through a fourth bevel gear 23, one end of the fourth transmission rod 22 extends to the outside of the housing 1, and a protection rod 24 is fixedly arranged at one end of the fourth transmission rod 22 located at the outside of the housing 1, so that a worker can be prevented from accidentally inserting a hand into the observation window 20 to cause damage in the molding process, and the protection performance is high.

Referring to fig. 1 to 3, a conveyor belt 21 is installed at the bottom of the housing 1 for conveying the formed alloy material.

Referring to fig. 1 and 2, an observation window 20 is disposed at the front end of the housing 1 for facilitating the internal observation of the worker.

The working principle is as follows: when the die is used, the driving gear 34 on the output shaft of the driving motor 9 enables the pressure lever 6 to drive the male die 4 to move towards the female die 3 under the matching with the rack 7, so as to form the alloy material in the hollow groove 30, in the moving process of the male die 4, the fifth bevel gear 31 at one end of the output shaft of the driving motor 9 drives the first bevel gear 11 provided with the first transmission rod 10 to rotate under the meshing action, the first bevel gear 11 at the other end of the first transmission rod 10 drives the second bevel gear 13 provided with the second transmission rod 12 to rotate under the meshing action, similarly, the second transmission rod 12 drives the thread telescopic column 16 to rotate through the third transmission rod 14, as the thread sleeve 32 is connected with the shell 1 through the bearing, and the thread sleeve 32 is matched with the thread telescopic column 16 through the thread, the protruding structure outside the limit column 17 can enable the thread telescopic column 16 not to rotate, therefore, under the rotation of the third bevel gear 15, the gradual shrinkage of the top block 18 can be realized, so that the top block 18 is gradually shrunk in the process that the male mold 4 approaches the female mold 3, the normal molding work cannot be influenced, after the molding is finished, the driving motor 9 reversely rotates, the pressure lever 6 drives the male mold to be separated from the female mold, under the cooperation of the bevel gear and the transmission rod, the top block 18 extends towards one side again, the molded alloy is ejected out of the female mold 3, and then falls onto the conveying belt 21 to move out of the molding equipment, after a synthetic material is molded, under the action of the spring 27 and the top plate 26, the material in the alloy feeding cavity 25 can be pushed to the upper end of the alloy guiding device 19, the roller 29 in the feeding mechanism 28 can synchronously rotate through the cooperation of the motor and the belt, the downward conveying of the alloy material above the interior can be realized, until the alloy material is contacted with the bottom of the alloy guiding device 19, under the action of the male die 4, alloy materials can enter the female die through the empty groove 30 for forming, when the male die 4 moves towards the female die 3, the output shaft of the other driving motor 9 drives the fourth bevel gear 23 provided with the fourth transmission rod 22 to rotate, so that the guard bar 24 swings at the front end of the shell 1, and the guard bar is reset due to the fact that the driving motor 9 rotates reversely when the male die 4 is separated.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. Alloy shaping automated production equipment, including casing (1), the inside of casing (1) is provided with becomes die cavity (2), female mould (3) are installed to the inside one side in die cavity (2), and female mould (3) pass through the bolt fastening with casing (1), the inside opposite side in die cavity (2) is provided with public mould (4), its characterized in that:

the die is characterized by further comprising a compression bar (6) which is fixedly arranged on one side of the male die (4), racks (7) are fixedly arranged at the front end and the rear end of the compression bar (6), a transmission cavity (5) is formed in one side inside the shell (1), driving motors (9) are fixedly arranged at the front end and the rear end of the transmission cavity (5), a driving gear (34) is arranged in the middle of an output shaft of each driving motor (9), the compression bar (6) is located between the driving gears (34), and the driving gears (34) are meshed with the racks (7);

the ejection block (18) is arranged on one side of the female die (3), the threaded telescopic column (16) is installed on one side of the ejection block (18), the ejection block (18) is connected with one end of the threaded telescopic column (16) through a bearing, the threaded sleeve (32) is installed outside the threaded telescopic column (16), and the outside of the threaded sleeve (32) is connected with the shell (1) through the bearing.

2. The alloy molding automatic production equipment according to claim 1, characterized in that: one of them the front end fixed mounting of driving motor (9) output shaft has fifth bevel gear (31), one side of fifth bevel gear (31) upper end is provided with first transfer line (10), the both ends of first transfer line (10) all are fixed and are provided with first bevel gear (11), and first bevel gear (11) that are located first transfer line (10) one side are connected with fifth bevel gear (31) meshing, second transfer line (12) are installed to one side of first transfer line (10) rear end, the both ends of second transfer line (12) all fixed mounting have second bevel gear (13), and second bevel gear (13) that are located second transfer line (12) one end are connected with first bevel gear (11) meshing of first transfer line (10) other end, the rear end of flexible post of screw thread (16) is provided with third transfer line (14), the both ends of third transfer line (14) all fixed third bevel gear (15) that are provided with, and third bevel gear (15) and third bevel gear (13) of third transfer line (14) one end are connected with second bevel gear (13) meshing.

3. The alloy molding automatic production equipment according to claim 2, characterized in that: a sixth bevel gear (33) is fixedly arranged at one end of the threaded sleeve (32), and the sixth bevel gear (33) is meshed and connected with a third bevel gear (15) at the other end of the third transmission rod (14).

4. The alloy molding automatic production equipment according to claim 1, characterized in that: the utility model discloses a thread telescopic column, including the flexible post of screw thread (16), the internally mounted of the flexible post of screw thread (16) has spacing post (17), and the one end and casing (1) welded fastening of spacing post (17), the outside of spacing post (17) is provided with four lugs that are annular equidistance and distribute, and lug and the inside cell body sliding connection of the flexible post of screw thread (16).

5. The automatic production equipment for alloy forming according to claim 1, wherein: an alloy material guide device (19) is arranged on the other side of the female die (3), material conveying mechanisms (28) are arranged on two sides of the middle position of the alloy material guide device (19), and an empty groove (30) is arranged below the rear end of the alloy material guide device (19).

6. The alloy molding automatic production equipment according to claim 5, characterized in that: the inside of defeated material mechanism (28) is provided with a plurality of gyro wheels (29) that distribute in proper order equidistance, accessible belt drive between the connecting axle of gyro wheel (29), mountable motor simultaneously on the connecting axle of outside gyro wheel (29), drive gyro wheel (29) synchronous rotation realizes the removal to the alloy material.

7. The alloy molding automatic production equipment according to claim 1, characterized in that: an alloy feeding cavity (25) is arranged above the forming cavity (2), a top plate (26) is arranged inside the alloy feeding cavity (25), the top plate (26) is connected with the alloy feeding cavity (25) in a sliding mode, a spring (27) is fixedly arranged between one side of the top plate (26) and the alloy feeding cavity (25), and alloy materials are placed on the other side of the top plate (26).

8. The alloy molding automatic production equipment according to claim 1, characterized in that: and a sixth bevel gear is mounted on an output shaft of the driving motor (9), a fourth transmission rod (22) is mounted at the upper end of the sixth bevel gear, the fourth transmission rod (22) is meshed with the sixth bevel gear through a fourth bevel gear (23), one end of the fourth transmission rod (22) extends to the outside of the shell (1), and a protection rod (24) is fixedly arranged at one end, located outside the shell (1), of the fourth transmission rod (22).

9. The alloy molding automatic production equipment according to claim 1, characterized in that: the bottom of the shell (1) is provided with a conveying belt (21).

10. The alloy molding automatic production equipment according to claim 8, characterized in that: an observation window (20) is arranged at the front end of the shell (1).