CN118143718A - Continuity conveyor is used in mould processing - Google Patents

Abstract

The invention discloses a continuous conveying device for mold processing, and relates to the technical field of conveying; to solve the problem of damage; the device specifically comprises a conveyor and a longitudinal lifting part arranged at a processing station of the conveyor, wherein the longitudinal lifting part comprises brackets symmetrically arranged on the outer walls of two sides of the conveyor, chucks arranged on the side walls of the chucks and a group of driving components for simultaneously driving the two groups of chucks; the clamping head comprises a sliding frame, an 'I' -shaped shaft fixed on the inner side wall of the sliding frame and 'L' -shaped clamping arms rotatably connected to the two sides of the 'I' -shaped shaft, the sliding frame is connected to the bracket in a sliding manner through a guide rod, and a clamping roller I is arranged at the upper end part of the 'L' -shaped clamping arms. According to the invention, the clamping head is arranged, the blank can be clamped by the first clamping roller, and the blank can be lifted by revolution so as to be separated from the conveyor, so that the conveyor does not need to be closed, and the damage caused by long-time friction between the blank and the conveyor in the processing process is prevented.

Description

Continuity conveyor is used in mould processing

Technical Field

The invention relates to the technical field of conveying, in particular to a continuous conveying device for die machining.

Background

When the die is used for processing, the blank is required to be cut firstly, then the blank is subjected to procedures such as milling and punching, and when the die is used for large-batch automatic production, the conveying device is required to be used for conveying the blank, so that the processing efficiency is improved.

Through retrieving, chinese patent publication No. CN 216444534U's patent discloses a conveying mechanism for mould processing, including casing, first stop gear, second stop gear and conveyer belt, first stop gear and second stop gear all set up in the top of casing, the conveyer belt sets up in the inside of casing, the front end fixed mounting of casing has the motor, the output of motor runs through and sees the casing transmission and be connected with the conveyer belt, the upper surface fixedly connected with baffle of casing, the front end of casing is kept away from one side welding of motor has the supporting seat.

The above patent suffers from the following disadvantages: the continuous conveying is carried out by using the conveying belt, but the conveying belt is required to be stopped due to the intermittent stopping conveying when the conveying belt is at a processing station, otherwise, the conveying belt and blanks are damaged by friction, and when the conveying belt is processed in a large scale, the power motor of the conveying belt is repeatedly started and stopped, so that the coil instant current is larger, and the coil is easy to overheat and damage.

To this end, the invention proposes a continuous conveyor for mold processing.

Disclosure of Invention

The invention aims to solve the defects in the prior art and provides a continuous conveying device for die processing.

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

a continuous conveying device for die processing comprises a conveyor and a longitudinal lifting part arranged at a processing station of the conveyor,

The longitudinal lifting part comprises brackets symmetrically arranged on the outer walls of two sides of the conveyor, chucks arranged on the side walls of the chucks and a group of driving assemblies for driving the two groups of chucks simultaneously;

The clamping head comprises a sliding frame, an 'I' -shaped shaft fixed on the inner side wall of the sliding frame and 'L' -shaped clamping arms rotatably connected to two sides of the 'I' -shaped shaft, the sliding frame is connected to the support in a sliding mode through a guide rod, a clamping roller I is arranged at the upper end part of the 'L' -shaped clamping arm, a clamping roller II is fixedly arranged at the lower end part of the 'L' -shaped clamping arm, and torsion springs are buckled on the opposite sides of the 'I' -shaped shaft and the 'L' -shaped clamping arm.

Preferably: the side wall of the sliding frame is fixedly provided with a limit column, and the outer wall of the L-shaped clamping arm is fixedly provided with a limit rod.

Further: the clamping roller is rotationally connected to the L-shaped clamping arm, the inner side wall of the L-shaped clamping arm is rotationally connected with the reversing shaft, the outer wall of the reversing shaft is connected with the first gear through a key, one side of the first clamping roller is fixedly provided with the second gear meshed with the first gear, and the reversing shaft is in transmission fit with the I-shaped shaft through the synchronous assembly.

Based on the scheme: one side of the support, which is positioned at the downstream of the conveying, is connected with a downstream baffle through a sliding rod in a sliding way, and the inner wall of the downstream baffle is embedded with a collision sensor.

Among the foregoing, the preferred one is: one side of the support, which is positioned at the upstream of the conveying, is connected with an upstream baffle plate in a sliding way through a second sliding rod.

As a further scheme of the invention: and the second sliding rod is fixed on the side wall of the guide rod.

Simultaneously, one side fixed mounting of support has the backup pad, and the inboard rotation of tip of backup pad is connected with the lever, and waist type hole has all been seted up at the both ends of lever, and one of them waist type hole is through spacing protruding one activity spacing cooperation in the lateral wall of guide bar, and another waist type hole is through spacing protruding two activity spacing cooperation in the lateral wall of slide bar one.

As a preferred embodiment of the present invention: the driving assembly comprises two sliding blocks which are respectively connected to the inner wall of the bracket in a sliding way and two screw rods which are respectively connected to the inner wall of the bracket in a rotating way, and the screw rods are connected to the inner wall of the sliding blocks through threads.

Simultaneously, the outer wall of the bottom of the conveyor is fixedly provided with a rotary driver, an output shaft of the rotary driver is connected with a belt wheel through a key, and the belt wheel is matched with the side walls of the two screw rods through a synchronous belt in a transmission manner.

As a more preferable scheme of the invention: the side wall of the sliding block is rotationally connected with a connecting rod, and the other end of the connecting rod is rotationally connected to the bottom of the sliding frame.

The beneficial effects of the invention are as follows:

1. According to the invention, the clamping head is arranged, the blank can be clamped by the clamping roller I, the blank can be lifted by revolution, and is separated from the conveyor, so that the conveyor is not required to be closed, damage caused by long-time friction between the blank and the conveyor in the machining process is prevented, the L-shaped clamping arm adopts an L-shaped structure, the clamping roller II is arranged at the other end of the L-shaped clamping arm, and can rotate to the bottom of the die along with continuous movement of the sliding frame to contact and support, so that the stability of support is improved, and blank displacement caused by longitudinal force in machining is prevented, thereby improving machining precision.

2. According to the invention, the synchronous component, the first gear and the second gear are arranged, so that the reversing shaft rotates along the axial line of the H-shaped shaft and simultaneously rotates the first clamping roller, the speed of lifting the blank is increased by utilizing the rotation, the second clamping roller can be more rapidly contacted with the bottom of the blank, the required transverse sliding stroke of the whole chuck can be reduced, the chuck can be more rapidly separated from the conveyor under the condition that the transmission speed of the driving component is unchanged, the friction time of the blank and the conveyor is reduced, abrasion is prevented, and the rotation of the first clamping roller is driven by the rotation of the L-shaped clamping arm, so that the power arrangement is saved, the control cost and the volume optimization are facilitated.

3. According to the invention, automatic control can be realized by arranging the downstream baffle to block and utilizing the collision sensor to generate the electric signal, and by arranging the upstream baffle, the subsequent misplaced or misplaced blanks can be temporarily blocked in the processing process, so that the damage caused by blank conveying collision when the processing is not finished can be prevented, and the reliability is increased.

4. According to the invention, the lever, the first limiting protrusion and the second limiting protrusion are arranged, so that the displacement of the first sliding rod and the position of the upstream baffle are synchronous with the guide rod, the guide rod can be comprehensively driven, the matching degree of the components is ensured, the power arrangement is saved, and the volume optimization and the cost control are facilitated.

5. According to the invention, the driving assembly is set to be a combination of the connecting rod, the sliding block and the screw rod, and the screw rod is synchronously driven by the synchronous belt, so that the motion states of the two chucks are completely consistent, the separated blank is positioned at the center, the position of the separated blank is positioned, the subsequent processing and positioning are facilitated, and the precision is improved.

Drawings

Fig. 1 is a schematic diagram of the overall structure of a continuous conveying device for mold processing according to the present invention;

fig. 2 is a schematic view of a longitudinal lifting part of a continuous conveying device for mold processing according to the present invention;

FIG. 3 is a schematic diagram of a chuck of the continuous conveying device for mold processing according to the present invention;

FIG. 4 is a schematic view of a part of a continuous conveying device for mold processing according to the present invention;

fig. 5 is a schematic diagram of a chuck structure of a continuous conveying device for mold processing according to the second embodiment of the present invention;

FIG. 6 is a schematic view of the downstream baffle and the upstream baffle of the continuous conveying device for mold processing according to the present invention;

FIG. 7 is a schematic diagram of the driving structure of the downstream baffle and the upstream baffle of the continuous conveying device for mold processing according to the present invention;

fig. 8 is a schematic diagram of a driving assembly of a continuous conveying device for mold processing according to the present invention.

In the figure: 1. a conveyor; 2. a longitudinal lifting part; 3. a chuck; 4. a bracket; 5. a drive assembly; 6. a guide rod; 7. a carriage; 8. an "I" shaped shaft; 9. an L-shaped clamping arm; 10. a first clamping roller; 11. a second clamping roller; 12. a torsion spring; 13. a limit column; 14. a limit rod; 15. a synchronization component; 16. a first gear; 17. a second gear; 18. a reversing shaft; 19. a collision sensor; 20. a downstream baffle; 21. a first slide bar; 22. a second slide bar; 23. an upstream baffle; 24. a support plate; 25. the first limit bulge is arranged; 26. a lever; 27. a waist-shaped hole; 28. a second limiting protrusion; 29. a connecting rod; 30. a slide block; 31. a screw rod; 32. a synchronous belt; 33. a belt wheel; 34. a rotary drive.

Detailed Description

The technical scheme of the invention is further described in detail below with reference to the specific embodiments.

Embodiments of the present invention are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the invention.

Example 1:

The continuous conveying device for die machining comprises a conveyor 1 and a longitudinal lifting part 2 arranged at a machining station of the conveyor 1, wherein the longitudinal lifting part 2 comprises brackets 4 symmetrically arranged on the outer walls of two sides of the conveyor 1, chucks 3 arranged on the side walls of the chucks 3 and a group of driving assemblies 5 for driving the chucks 3 of two groups simultaneously.

In the present embodiment, the specific type of the conveyor 1 is not limited, and may be any one of a belt conveyor, a chain conveyor, and a roller conveyor, preferably a chain conveyor, and the conveying plane thereof is relatively flat and has good support.

The chuck 3 comprises a sliding frame 7, an 'I' -shaped shaft 8 fixed on the inner side wall of the sliding frame 7 and 'L' -shaped clamping arms 9 rotatably connected to two sides of the 'I' -shaped shaft 8, wherein the sliding frame 7 is slidably connected to the bracket 4 through a guide rod 6, a clamping roller I10 is arranged at the upper end part of the 'L' -shaped clamping arms 9, a clamping roller II 11 is fixedly arranged at the lower end part of the 'L' -shaped clamping arms 9, and torsion springs 12 are buckled on the opposite sides of the 'I' -shaped shaft 8 and the 'L' -shaped clamping arms 9.

When the die blank is used, a die blank is placed on the conveying upstream of the conveyor 1 by using a manual or mechanical arm and the like, when the blank is conveyed to a processing station, the driving assembly 5 drives the two groups of chucks 3 to be close to each other, in the process, the sliding frame 7 drives the L-shaped clamping arm 9 to synchronously move with the clamping roller I10 and the clamping roller II 11 until the clamping roller I10 contacts with the side wall of the die, the clamping roller I10 is limited, at the moment, the sliding frame 7 continues to move, the clamping roller I10 drives the L-shaped clamping arm 9 to rotate relative to the I-shaped shaft 8, in the process, a torsion force is provided by the torsion spring 12, so that a larger friction force exists between the clamping roller I10 and the die, and in the process, the clamping roller I10 is driven to relatively rise to be separated from the conveyor 1, so that the conveyor 1 is not required to be closed, and the clamping roller II 11 can rotate to the bottom of the die to be contacted and supported along with the continuous movement of the sliding frame 7.

This device, through setting up chuck 3, utilize pinch roller one 10 can carry out the centre gripping to the blank, and still available revolution makes the blank promote, thereby with conveyer 1 separation, thereby need not to close conveyer 1, thereby prevent the damage that causes because of the long-time friction of course of working blank with conveyer 1, and "L" arm 9 adopts L type structure, its other end sets up pinch roller two 11, along with the continuous removal of balladeur train 7, pinch roller two 11 can rotate to the bottom of mould, contact and support, thereby increased the stability of support, the longitudinal force that appears when preventing to process leads to the blank displacement, thereby increase machining precision.

In order to solve the limit problem; as shown in fig. 4, a limit post 13 is welded on the side wall of the carriage 7, and a limit rod 14 is welded on the outer wall of the L-shaped clamp arm 9. The limiting post 13 and the limiting rod 14 can limit each other, so that the reset position of the L-shaped clamp arm 9 is limited.

To solve the efficiency problem; as shown in fig. 5, the first clamping roller 10 is rotatably connected to the L-shaped clamping arm 9, the inner side wall of the L-shaped clamping arm 9 is rotatably connected to a reversing shaft 18, the outer wall of the reversing shaft 18 is connected to a first gear 16 through a key, a second gear 17 meshed with the first gear 16 is fixed on one side of the first clamping roller 10, and the reversing shaft 18 is in transmission fit with the h-shaped shaft 8 through a synchronizing assembly 15.

When the L-shaped clamping arm 9 drives the clamping roller I10 to rotate relative to the I-shaped shaft 8, the gear I16 also rotates along the axis of the I-shaped shaft 8, so that the gear I16 rotates by the cooperation of the synchronous assembly 15, and the gear II 17 is driven to rotate, so that the clamping roller I10 rotates.

The device can enable the reversing shaft 18 to rotate along the axis of the H-shaped shaft 8 and enable the clamping roller I10 to rotate at the same time by arranging the synchronous component 15, the gear I16 and the gear II 17, so that the clamping roller II 11 can be enabled to be in quicker contact with the bottom of the blank by utilizing the rotation to increase the speed of lifting the blank, the transverse sliding stroke required by the whole clamping head 3 can be reduced, the clamping head 3 can be enabled to be separated from the conveyor 1 more quickly under the condition that the transmission speed of the driving component 5 is unchanged, the friction time of the blank and the conveyor 1 is reduced, abrasion is prevented, and the rotation of the clamping roller I10 depends on the rotation driving of the L-shaped clamping arm 9, so that power arrangement is saved, and the control cost and the volume optimization are facilitated.

In order to solve the material blocking problem; as shown in fig. 6, the downstream baffle 20 is slidably connected to the side of the support 4 located downstream of the conveying through the first slide rod 21, and the collision sensor 19 is embedded in the inner wall of the downstream baffle 20.

The upstream baffle 23 is connected to the side of the support 4 located at the upstream of the conveying through a second slide rod 22 in a sliding manner.

When the blanks are conveyed by the conveyor 1, the blanks can collide with the collision sensor 19 at the same time, the driving assembly 5 is controlled to be started by generating an electric signal, after the driving assembly 5 drives the chucks 3 to separate the blanks, the downstream baffle 20 can be relatively contracted, the chucks 3 are rapidly contacted with the blanks to limit at the moment that the downstream baffle 20 loses limit, the first process chuck roller 10 can be driven by the conveyor 1 to displace for a small distance, meanwhile, the upstream baffle 23 can stretch out to block until the process is finished, the chucks 3 are reset, the relative speed of resetting the chucks 3 is slow, the chucks 3 are reset until the chucks 3 cannot clamp the blanks and the downstream baffle 20 cannot limit the blanks, and the chucks 3 continue to reset after the chucks 20 are driven by the conveyor 1 to pass through the downstream baffle 20, so that the downstream baffle 20 is completely extended, and the upstream baffle 23 is contracted and reset in the process.

This device blocks through setting up the low reaches baffle 20, and utilizes collision sensor 19 to produce the signal of telecommunication, can realize automatic control to through setting up the upper reaches baffle 23 in the upper reaches, it can carry out the interim stop to follow-up misplacement or the blank that the mistake was carried in the course of working, thereby can prevent the damage that the blank carried the collision caused when not accomplishing, increased the reliability.

To solve the driving problem; as shown in fig. 7, the second slide bar 22 is fixed on the side wall of the guide bar 6, one side of the support 4 is welded with a support plate 24, the inner side of the end of the support plate 24 is rotatably connected with a lever 26, two ends of the lever 26 are provided with waist-shaped holes 27, one waist-shaped hole 27 is movably and limitedly matched with the side wall of the guide bar 6 through a first limiting protrusion 25, and the other waist-shaped hole 27 is movably and limitedly matched with the side wall of the first slide bar 21 through a second limiting protrusion 28.

When the guide rod 6 moves, the guide rod can drive the upstream baffle 23 to move in the same direction and at the same speed through the second slide rod 22, the lever 26 is rotated through the first limiting protrusion 25, and the first slide rod 21 is driven to move in the same speed and in the opposite direction through the second limiting protrusion 28.

The device is provided with the lever 26, the first limiting bulge 25 and the second limiting bulge 28, so that the displacement of the first sliding rod 21 and the position of the upstream baffle 23 can be synchronous with the guide rod 6, the device can be comprehensively driven, the matching degree of each part is ensured, the power arrangement is saved, and the volume optimization and the cost control are facilitated.

In this embodiment, when the die blank is placed on the upstream of the conveyor 1 by using a manual or mechanical arm, etc., and when the blank is conveyed to the processing station, the driving component 5 drives the two groups of chucks 3 to approach each other, in this process, the carriage 7 drives the L-shaped chuck arm 9 to move synchronously with the first chuck roller 10 and the second chuck roller 11 until the first chuck roller 10 contacts the side wall of the die, the first chuck roller 10 is limited, at this moment, the carriage 7 continues to move, the first chuck roller 10 drives the L-shaped chuck arm 9 to rotate relative to the h-shaped shaft 8, in this process, a torsion force is provided by the torsion spring 12, so that a large friction force exists between the first chuck roller 10 and the die, and when the first chuck roller 10 rotates, the die is driven to rise relatively and separate from the conveyor 1, so that the conveyor 1 is not required to be closed, and as the carriage 7 continues to move, the second chuck roller 11 rotates to the bottom of the die, the contact and support are carried out, when the L-shaped clamping arm 9 drives the clamping roller I10 to rotate relative to the I-shaped shaft 8, the gear I16 also rotates along the axis of the I-shaped shaft 8, so that the gear I16 rotates by the cooperation of the synchronous component 15, the gear II 17 is driven to rotate, the clamping roller I10 is driven to rotate, in addition, when a blank is conveyed by the conveyor 1, the blank also collides with the collision sensor 19, the electric signal is generated to control the driving component 5 to start, after the driving component 5 drives the chuck 3 to separate the blank, the downstream baffle 20 is relatively contracted, the chuck 3 rapidly contacts the blank to limit at the moment that the downstream baffle 20 loses limit on the blank, the clamping roller I10 is driven by the conveyor 1 to displace a small distance, the upstream baffle 23 stretches out to block until the machining is finished, the chuck 3 is reset, the relative speed of resetting the chuck 3 is slow, the chuck 3 is reset until the chuck 3 can not clamp the blank and the downstream baffle 20 can not limit the blank, the blank is driven by the conveyor 1 to pass through the downstream baffle 20, so that the downstream baffle 20 is fully extended, the upstream baffle 23 is retracted and reset in the process, meanwhile, when the guide rod 6 moves, the guide rod can drive the upstream baffle 23 to move in the same direction and at the same speed through the second slide rod 22, the first limiting protrusion 25 enables the lever 26 to rotate, and the second limiting protrusion 28 drives the first slide rod 21 to move in the same speed and in the opposite direction.

Example 2:

As shown in fig. 8, the continuous conveying device for mold processing aims to solve the problem of precision; the present example was modified on the basis of example 1 as follows: the driving assembly 5 comprises two sliding blocks 30 which are respectively and slidably connected to the inner wall of the bracket 4, and two screw rods 31 which are respectively and rotatably connected to the inner wall of the bracket 4, wherein the screw rods 31 are connected to the inner wall of the sliding blocks 30 through threads, the outer wall of the bottom of the conveyor 1 is fixedly provided with a rotary driver 34 through bolts, an output shaft of the rotary driver 34 is connected with a belt wheel 33 through a key, and the belt wheel 33 is in transmission fit with the side walls of the two screw rods 31 through a synchronous belt 32.

The side wall of the sliding block 30 is rotatably connected with a connecting rod 29, and the other end of the connecting rod 29 is rotatably connected with the bottom of the sliding frame 7.

In use, when the rotary driver 34 is started, it can drive the belt wheel 33 to rotate, so that the synchronous belt 32 drives the two screw rods 31 to rotate, and the slide block 30 can be driven to move by using the threaded connection relationship, and then the slide frame 7 is driven to move by the connecting rod 29.

According to the device, the driving assembly 5 is arranged to be a combination of the connecting rod 29, the sliding block 30 and the screw rod 31, and the screw rod 31 is synchronously driven by the synchronous belt 32, so that the motion states of the two chucks 3 are completely consistent, the separated blanks are positioned in the center, the positions of the blanks are positioned, the subsequent processing and positioning are facilitated, and the precision is improved.

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should make equivalent substitutions or modifications according to the technical scheme of the present invention and the inventive concept thereof, and should be covered by the scope of the present invention.

Claims (10)

1. The continuous conveying device for die processing comprises a conveyor (1) and a longitudinal lifting part (2) arranged at a processing station of the conveyor (1), and is characterized in that,

The longitudinal lifting part (2) comprises brackets (4) symmetrically arranged on the outer walls of two sides of the conveyor (1), clamping heads (3) arranged on the side walls of the clamping heads (3) and a group of driving assemblies (5) for driving the two groups of clamping heads (3) simultaneously;

The chuck (3) comprises a sliding frame (7), an 'I' -shaped shaft (8) fixed on the inner side wall of the sliding frame (7) and 'L' -shaped clamping arms (9) rotationally connected to two sides of the 'I' -shaped shaft (8), the sliding frame (7) is slidably connected to the bracket (4) through a guide rod (6), a clamping roller I (10) is arranged at the upper end part of the 'L' -shaped clamping arms (9), a clamping roller II (11) is fixedly arranged at the lower end part of the 'L' -shaped clamping arms (9), and torsion springs (12) are buckled on the opposite sides of the 'I' -shaped shaft (8) and the 'L' -shaped clamping arms (9).

2. The continuous conveying device for mold processing according to claim 1, wherein a limit post (13) is fixedly arranged on the side wall of the carriage (7), and a limit rod (14) is fixedly arranged on the outer wall of the L-shaped clamping arm (9).

3. The continuous conveying device for mold processing according to claim 1, wherein the first clamping roller (10) is rotatably connected to an L-shaped clamping arm (9), the inner side wall of the L-shaped clamping arm (9) is rotatably connected with a reversing shaft (18), the outer wall of the reversing shaft (18) is connected with a first gear (16) through a key, one side of the first clamping roller (10) is fixedly provided with a second gear (17) meshed with the first gear (16), and the reversing shaft (18) is in transmission fit with the I-shaped shaft (8) through a synchronizing assembly (15).

4. A continuous conveying device for die processing according to claim 1, wherein a downstream baffle (20) is slidably connected to one side of the support (4) located downstream in conveying through a first slide rod (21), and an impact sensor (19) is embedded in the inner wall of the downstream baffle (20).

5. A continuous conveyor for mould processing according to claim 1, characterized in that the side of the support (4) upstream of the conveyor is slidingly connected with an upstream baffle (23) by means of a second slide bar (22).

6. The continuous conveyor for mold processing according to claim 5, wherein the second slide bar (22) is fixed to a side wall of the guide bar (6).

7. The continuous conveying device for mold processing according to claim 4, wherein a supporting plate (24) is fixedly installed on one side of the support (4), a lever (26) is rotatably connected to the inner side of the end portion of the supporting plate (24), waist-shaped holes (27) are formed in two ends of the lever (26), one waist-shaped hole (27) is movably and limitedly matched with the side wall of the guide rod (6) through a first limiting protrusion (25), and the other waist-shaped hole (27) is movably and limitedly matched with the side wall of the first sliding rod (21) through a second limiting protrusion (28).

8. A continuous conveying device for die processing according to claim 1, wherein the driving assembly (5) comprises two sliding blocks (30) which are respectively connected with the inner wall of the bracket (4) in a sliding manner and two screw rods (31) which are respectively connected with the inner wall of the bracket (4) in a rotating manner, and the screw rods (31) are connected with the inner wall of the sliding blocks (30) through threads.

9. The continuous conveying device for mold processing according to claim 8, wherein a rotary driver (34) is fixedly installed on the outer wall of the bottom of the conveyor (1), an output shaft of the rotary driver (34) is connected with a belt wheel (33) through a key, and the belt wheel (33) is in transmission fit with the side walls of the two screw rods (31) through a synchronous belt (32).

10. The continuous conveyor for mold processing according to claim 9, wherein the side wall of the slider (30) is rotatably connected to a link (29), and the other end of the link (29) is rotatably connected to the bottom of the carriage (7).