CN115077241A - Transport mechanism in vacuum furnace and vacuum furnace - Google Patents

Abstract

The invention discloses a conveying mechanism in a vacuum furnace and the vacuum furnace, and relates to the field of vacuum furnaces. According to the invention, through the arrangement of the base structure and the conveying structure, when the device is used, the base structure is directly laid in the vacuum furnace main body, the mutual matching of the fixed supporting legs and the fixed base is utilized to ensure that one path of the conveying mechanism is smooth, materials can be directly conveyed to the deep part of the vacuum furnace main body, meanwhile, the sliding material seat adaptive grooves and the fixed base adaptive grooves on the fixed base and the sliding material seat can be matched with the material bearing frame, so that the smoothness of the loading and unloading process is ensured, the alignment time is avoided due to the fixed position, the efficiency is higher, the possibility of contact between workers and high-temperature workpieces is also avoided, and the safety of the device is further improved.

Description

Transport mechanism in vacuum furnace and vacuum furnace

Technical Field

The invention relates to the technical field of vacuum furnaces, in particular to a conveying mechanism in a vacuum furnace and the vacuum furnace.

Background

The vacuum furnace is characterized in that a vacuum system (formed by elaborately assembling elements such as a vacuum pump, a vacuum measuring device, a vacuum valve and the like) is utilized to discharge partial substances in a furnace chamber in a specific space of the furnace chamber, so that the pressure in the furnace chamber is less than a standard atmospheric pressure, and the space in the furnace chamber realizes a vacuum state, namely the vacuum furnace.

Among the prior art, often utilize the vacuum furnace to process the work piece, but because the degree of depth of vacuum furnace is general darker, adopt artifical outside reinforced mode, the time of aiming at is long, not only efficiency is low, still causes the mistake easily to the inner wall of vacuum furnace and touches the injury, and the work piece temperature that has just passed through the processing is higher moreover, still has certain danger, consequently needs a vacuum furnace in transport mechanism and vacuum furnace to satisfy people's demand.

Disclosure of Invention

The invention aims to provide a conveying mechanism in a vacuum furnace and the vacuum furnace, and aims to solve the problems that the vacuum furnace proposed in the background art is generally deep in depth, long in alignment time due to the adoption of a manual external feeding mode, low in efficiency, prone to causing mistaken touch damage to the inner wall of the vacuum furnace, high in temperature of a workpiece which is just processed and dangerous to a certain extent.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a transport mechanism and vacuum furnace in vacuum furnace, includes the vacuum furnace main part, movable mounting has the side to open sealed lid in the vacuum furnace main part, and the side of vacuum furnace main part is equipped with the electrical control box, one side of vacuum furnace main part is equipped with goes up unloading structure, fixed mounting has base structure on the inner wall of vacuum furnace main part, and base structure fixed mounting is on the bottom side inner wall of vacuum furnace main part, and last slidable mounting of base structure has the material transporting structure, fixed mounting has the drive structure on the top side inner wall of vacuum furnace main part, and the drive structure contacts with the material transporting structure.

In the technical scheme, when the device is used, the base structure is directly laid in the inside of the vacuum furnace main body, utilize mutually supporting of fixed stay foot and unable adjustment base, guarantee that transporting material mechanism's unobstructed all the way, can directly deliver to the depths of vacuum furnace main body with the material, sliding material seat adaptation groove and unable adjustment base adaptation groove on unable adjustment base and the sliding material seat can bear frame looks adaptation with the material simultaneously, the unobstructed of unloading process on the assurance, because the rigidity, thereby the time of aiming at has been avoided, higher efficiency has, the possibility of workman and high temperature workpiece contact has also been avoided simultaneously, the security of device has further been improved.

Preferably, go up unloading structure trapped orbit, movable base plate, flexible bracing piece, installation box, material and bear the frame, two trapped orbits fixed mounting subaerial, movable base plate slidable mounting is in the top side of two trapped orbits, and two flexible bracing pieces fixed mounting are in the top side of movable base plate, and installation box fixed mounting is in the top side of two flexible bracing pieces, and two materials bear frame fixed mounting on the side that the installation box is close to the vacuum furnace main part. The utilization drives actuating cylinder drive installation box relocation, thereby it bears the position of frame and work piece to change the material, make the work piece remove to suitable position, the stability of installation box can be guaranteed to two flexible bracing pieces, drive movable base plate slides on fixed track, thereby bear the frame with the material and the inside that the work piece removed to the vacuum furnace main part, then reduce the position of installation box, make two materials bear the frame and pass sliding material seat adaptation groove and unable adjustment base adaptation groove in proper order, can leave the top side of work piece at sliding material seat.

Preferably, the top side of the movable base plate is fixedly provided with a driving cylinder, and the output end of the driving cylinder is fixedly arranged at the bottom side of the mounting box body. The driving cylinder is used for driving the mounting box body to change the position, so that the positions of the material bearing frame and the workpiece are changed.

Preferably, the base structure comprises fixed supporting feet and fixed bases, the fixed bases are symmetrically and fixedly installed on the inner wall of the bottom side of the vacuum furnace main body, and the fixed supporting feet are fixedly installed at the top ends of the fixed bases. The fixed supporting legs and the fixed base are matched with each other to stably support the position of the sliding material seat.

Preferably, the fixed base is of a U-shaped structure, the concave end of the fixed base is positioned on the top side, and two fixed base adapting grooves are formed in the fixed base. The two material bearing frames sequentially penetrate through the sliding material seat adaptation grooves and the fixed base adaptation grooves, and then the workpiece can be left on the top side of the sliding material seat.

Preferably, the material transporting structure comprises a sliding material seat, the vacuum furnace main body is slidably mounted in a groove of the fixed base, two sliding material seat adaptation grooves are formed in the sliding material seat and communicated with the two fixed base adaptation grooves, and the two sliding material seat adaptation grooves and the two fixed base adaptation grooves are matched with the two material bearing frames. The sliding material seat that removes drives T type slider and slides in T type spout for sliding material seat receives the influence of T type spout through T type slider, thereby remains stable at the in-process that removes.

Preferably, T-shaped sliding grooves are formed in the inner walls of the two sides of the fixed base, T-shaped sliding blocks are installed in the two T-shaped sliding grooves in a rotating mode, and the two T-shaped sliding blocks are fixedly installed on the two sides of the sliding material seat respectively. The sliding material seat that removes drives T type slider and slides in T type spout for sliding material seat receives the influence of T type spout through T type slider, thereby remains stable at the in-process that removes.

Preferably, the drive structure includes that fixed mounting frame, material frame drive actuating cylinder, actuating lever, connecting block, and fixed mounting frame fixed mounting is in the top side of vacuum furnace main part, and two material frame drive actuating cylinder equal fixed mounting are in fixed mounting frame's same side, and two connecting block equal fixed mounting are in the top side of slip material seat, and the one end of two actuating levers is rotated respectively and is installed in the one side that two connecting blocks kept away from each other, and the other end of two actuating levers rotates respectively and installs on the output of two material frame drive actuating cylinders. The material rack driving cylinder is started, so that the output end of the material rack driving cylinder utilizes the driving hole and the driving shaft to drive the driving rod to move, the other end of the driving rod utilizes the connecting hole and the connecting shaft to be matched with each other to drive the connecting block to move when the driving rod moves, and the two moving connecting blocks drive the sliding material seat to slide on the inner wall of the fixed base.

Preferably, two the actuating lever is close to the one end that the material frame drove actuating cylinder and has all seted up the drive hole, and the drive shaft is all installed in two drive holes rotation, and two drive shafts are fixed mounting respectively on two fixed mounting bracket's output. The output end of the material frame driving cylinder drives the driving rod to move by utilizing the driving hole and the driving shaft.

Preferably, two all seted up the connecting hole on the connecting block, all rotated in two connecting holes and installed the connecting axle, two connecting axles respectively fixed mounting be in the one side that two actuating levers are close to each other. The other end of the driving rod drives the connecting block to move by utilizing the mutual matching of the connecting hole and the connecting shaft while moving.

The invention has the beneficial effects that:

according to the invention, through the arrangement of the base structure and the conveying structure, when the device is used, the base structure is directly laid in the vacuum furnace main body, the mutual matching of the fixed supporting legs and the fixed base is utilized to ensure that one path of the conveying mechanism is smooth, materials can be directly conveyed to the deep part of the vacuum furnace main body, meanwhile, the sliding material seat adaptation grooves and the fixed base adaptation grooves on the fixed base and the sliding material seat can be adapted to the material bearing frame, so that the smoothness of the loading and unloading process is ensured, the alignment time is avoided due to the fixed position, the efficiency is higher, the possibility of contact between workers and high-temperature workpieces is also avoided, and the safety of the device is further improved.

According to the invention, through the arrangement of the feeding and discharging structure, the automatic machine is used for feeding and discharging, so that compared with the manual operation, the precision and the efficiency are better, the efficient use of the device is ensured, and the possibility that workers contact high-temperature workpieces is further avoided.

According to the invention, through the arrangement of the driving structure, the material rack is used for driving the air cylinder and the driving rod to be matched with each other, so that the effect of driving the sliding material seat to move in a reciprocating manner is realized, and the automatic feeding and discharging capability is realized when a workpiece is machined.

Drawings

FIG. 1 is a schematic perspective view of a transportation mechanism in a vacuum furnace and the vacuum furnace according to the present invention;

FIG. 2 is a schematic view of the internal structure of a vacuum furnace and a conveying mechanism therein according to the present invention;

FIG. 3 is a schematic structural view of a portion A in FIG. 2 of a vacuum furnace and a conveying mechanism in the vacuum furnace according to the present invention;

FIG. 4 is a schematic structural view of a conveying mechanism in a vacuum furnace and a loading and unloading structure of the vacuum furnace according to the present invention;

FIG. 5 is a schematic structural diagram of a conveying mechanism in a vacuum furnace and a driving structure of the vacuum furnace according to the present invention;

fig. 6 is a schematic structural diagram of a conveying mechanism in a vacuum furnace and a material conveying structure of the vacuum furnace according to the present invention.

In the figure: 1. a vacuum furnace main body; 2. the sealing cover is opened on the side; 3. an electrical control box; 4. fixing a track; 5. a movable base plate; 6. a telescopic supporting rod; 7. installing a box body; 8. a material carrying frame; 9. a driving cylinder; 10. fixing the supporting legs; 11. a fixed base; 12. a sliding material seat; 13. a T-shaped chute; 14. a T-shaped slider; 15. a sliding material seat adapting groove; 16. a fixed base adaptation groove; 17. fixing the mounting rack; 18. the material frame drives the air cylinder; 19. a drive rod; 20. connecting blocks; 21. a drive aperture; 22. a drive shaft; 23. connecting holes; 24. and (7) connecting the shafts.

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, a conveying mechanism in a vacuum furnace and a vacuum furnace comprise a vacuum furnace main body 1, a side-opening sealing cover 2 is movably installed on the vacuum furnace main body 1, an electrical control box 3 is arranged on the side surface of the vacuum furnace main body 1, a feeding and discharging structure is arranged on one side of the vacuum furnace main body 1, a base structure is fixedly installed on the inner wall of the vacuum furnace main body 1, the base structure is fixedly installed on the inner wall of the bottom side of the vacuum furnace main body 1, a material conveying structure is slidably installed on the base structure, a driving structure is fixedly installed on the inner wall of the top side of the vacuum furnace main body 1, the driving structure is contacted with the material conveying structure, when the device is used, the vacuum furnace main body 1 needs to be started, the mounting box body 7 is driven to change the position by a driving cylinder 9, so that the positions of a material bearing frame 8 and a workpiece are changed to move to a proper position, and the two telescopic support rods 6 can ensure the stability of the mounting box body 7, the movable base plate 5 is driven to slide on the fixed rail 4, so that the material bearing frames 8 and the workpieces are moved to the inside of the vacuum furnace main body 1, then the position of the installation box body 7 is lowered, the two material bearing frames 8 sequentially pass through the sliding material seat adaptation groove 15 and the fixed base adaptation groove 16, so that the workpieces can be left on the top side of the sliding material seat 12, at the moment, the feeding and discharging structure can be moved back to the original position, so that the device is restored, the fixed supporting feet 10 and the fixed base 11 are mutually matched to stably support the position of the sliding material seat 12, at the moment, the material frame driving cylinder 18 is started, so that the output end of the material frame driving cylinder 18 drives the driving rod 19 to move by using the driving hole 21 and the driving shaft 22, the driving rod 19 moves by using the mutual matching of the connecting hole 23 and the connecting shaft 24 at the other end of the driving rod 20, the two moving connecting rods 20 drive the sliding material seat 12 to slide on the inner wall of the fixed base 11, the sliding material seat 12 that removes drives T type slider 14 and slides in T type spout 13 for sliding material seat 12 receives the influence of T type spout 13 through T type slider 14, thereby keeps stable at the in-process that removes, waits for after the work piece processing is accomplished, drives the mode that actuating lever 19 was driven to 18 through the material frame, obtains position with sliding material seat 12 and recovers, and unloading structure on the cooperation can realize the automation of whole set of flow and go on.

Further, the feeding and discharging structure fixed rails 4, the movable base plate 5, the telescopic supporting rods 6, the mounting box 7 and the material bearing frame 8 are fixed on the ground, the movable base plate 5 is slidably mounted on the top sides of the two fixed rails 4, the two telescopic supporting rods 6 are fixedly mounted on the top side of the movable base plate 5, the mounting box 7 is fixedly mounted on the top sides of the two telescopic supporting rods 6, the two material bearing frames 8 are fixedly mounted on the side surfaces, close to the vacuum furnace main body 1, of the mounting box 7, the driving cylinder 9 is utilized to drive the mounting box 7 to change the position, so that the positions of the material bearing frame 8 and a workpiece are changed, the workpiece is moved to a proper position, the two telescopic supporting rods 6 can ensure the stability of the mounting box 7, the movable base plate 5 is driven to slide on the fixed rails 4, so that the material bearing frame 8 and the workpiece are moved to the inside the vacuum furnace main body 1, the position of the mounting box 7 is then lowered so that the two material carriers 8 pass through the sliding material holder adapter slots 15 and the fixed base adapter slots 16 in succession, i.e. leaving the work piece on the top side of the sliding material holder 12.

Further, a driving cylinder 9 is fixedly mounted on the top side of the movable base plate 5, an output end of the driving cylinder 9 is fixedly mounted on the bottom side of the mounting box 7, and the driving cylinder 9 is used for driving the mounting box 7 to change positions, so that the positions of the material bearing frame 8 and the workpiece are changed.

Further, the base structure includes fixed supporting legs 10 and unable adjustment base 11, and a plurality of unable adjustment base 11 symmetry fixed mounting are on the bottom side inner wall of vacuum furnace main part 1, and fixed supporting legs 10 fixed mounting is on a plurality of unable adjustment base 11's top, and fixed supporting legs 10 and unable adjustment base 11 mutually support the position stability of sliding material seat 12.

Further, unable adjustment base 11 is U type structure, and its concave surface end is located the top side, has seted up two unable adjustment base adaptation grooves 16 on unable adjustment base 11, and two materials bear frame 8 and pass sliding material seat adaptation groove 15 and unable adjustment base adaptation groove 16 in proper order, can stay the top side of sliding material seat 12 with the work piece.

Further, the fortune material structure includes sliding material seat 12, 1 slidable mounting of vacuum furnace main part is in unable adjustment base 11's recess, two sliding material seat adaptation grooves 15 have been seted up on sliding material seat 12, two sliding material seat adaptation grooves 15 and two unable adjustment base adaptation grooves 16 are linked together, two sliding material seat adaptation grooves 15 and two unable adjustment base adaptation grooves 16 all bear 8 looks adaptations with two materials, the sliding material seat 12 that removes drives T type slider 14 and slides in T type spout 13, make sliding material seat 12 receive T type spout 13's influence through T type slider 14, thereby in-process at the removal remains stable.

Further, T type spout 13 has all been seted up on unable adjustment base 11's the both sides inner wall, all rotate in two T type spouts 13 and install T type slider 14, two T type sliders 14 are fixed mounting respectively in the both sides of sliding material seat 12, the sliding material seat 12 that removes drives T type slider 14 and slides in T type spout 13 for sliding material seat 12 receives T type spout 13's influence through T type slider 14, thereby the in-process at the removal remains stable.

Further, the driving structure comprises a fixed mounting frame 17, material frame driving cylinders 18, driving rods 19 and connecting blocks 20, the fixed mounting frame 17 is fixedly mounted on the top side of the vacuum furnace main body 1, the two material frame driving cylinders 18 are fixedly mounted on the same side surface of the fixed mounting frame 17, the two connecting blocks 20 are fixedly mounted on the top side of the sliding material seat 12, one ends of the two driving rods 19 are respectively rotatably mounted on one side, away from each other, of the two connecting blocks 20, the other ends of the two driving rods 19 are respectively rotatably mounted on the output ends of the two material frame driving cylinders 18, the material frame driving cylinders 18 are started, so that the output ends of the material frame driving cylinders 18 drive the driving rods 19 to move by utilizing the driving holes 21 and the driving shafts 22, the other ends of the driving rods 19 drive the connecting blocks 20 to move by utilizing the mutual matching of the connecting holes 23 and the connecting shafts 24 when the driving rods are in motion, the two movable connecting blocks 20 drive the sliding material seat 12 to slide on the inner wall of the fixed base 11.

Furthermore, driving holes 21 are formed in one ends, close to the material frame driving air cylinders 18, of the two driving rods 19, driving shafts 22 are rotatably mounted in the two driving holes 21, the two driving shafts 22 are fixedly mounted at the output ends of the two fixed mounting frames 17 respectively, and the output ends of the material frame driving air cylinders 18 drive the driving rods 19 to move through the driving holes 21 and the driving shafts 22.

Furthermore, connecting holes 23 are formed in the two connecting blocks 20, connecting shafts 24 are rotatably mounted in the two connecting holes 23, the two connecting shafts 24 are fixedly mounted on one sides, close to the two driving rods 19, of the two driving rods 19 respectively, and the other ends of the driving rods 19 move by utilizing the mutual matching of the connecting holes 23 and the connecting shafts 24 to drive the connecting blocks 20.

The working principle of the invention is as follows:

when the device is used, firstly, the vacuum furnace main body 1 needs to be started, the mounting box body 7 is driven by the driving cylinder 9 to change the position, so that the positions of the material bearing frame 8 and the workpiece are changed, the workpiece is moved to a proper position, the two telescopic supporting rods 6 can ensure the stability of the mounting box body 7, the movable base plate 5 is driven to slide on the fixed rail 4, so that the material bearing frame 8 and the workpiece are moved to the inside of the vacuum furnace main body 1, then the position of the mounting box body 7 is lowered, so that the two material bearing frames 8 sequentially penetrate through the sliding material seat adapting groove 15 and the fixed base adapting groove 16, the workpiece can be remained at the top side of the sliding material seat 12, at the moment, the loading and unloading structure can be moved back to the original position, so that the restoration of the device is realized, the fixed supporting feet 10 and the fixed base 11 are mutually matched to stably support the position of the sliding material seat 12, at this moment, the material rack driving cylinder 18 is started, so that the output end of the material rack driving cylinder 18 drives the driving rod 19 to move by utilizing the driving hole 21 and the driving shaft 22, the other end of the driving rod 19 moves by utilizing the mutual matching of the connecting hole 23 and the connecting shaft 24 to drive the connecting block 20 to move, the two moving connecting blocks 20 drive the sliding material seat 12 to slide on the inner wall of the fixed base 11, the moving sliding material seat 12 drives the T-shaped sliding block 14 to slide in the T-shaped sliding groove 13, so that the sliding material seat 12 is influenced by the T-shaped sliding groove 13 through the T-shaped sliding block 14, the moving process is stable, after the workpiece is processed, the position of the sliding material seat 12 is restored by utilizing the mode that the material rack driving cylinder 18 drives the driving rod 19, and the automation of the whole process can be realized by matching with a feeding and discharging structure.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (10)

1. The utility model provides a transport mechanism and vacuum furnace in vacuum furnace, includes vacuum furnace main part (1), its characterized in that: the utility model discloses a vacuum furnace, including vacuum furnace main part (1), movable mounting has the side to open sealed lid (2) on vacuum furnace main part (1), and the side of vacuum furnace main part (1) is equipped with electrical control box (3), one side of vacuum furnace main part (1) is equipped with goes up unloading structure, fixed mounting has the base structure on the inner wall of vacuum furnace main part (1), and base structure fixed mounting has the fortune material structure on the bottom side inner wall of vacuum furnace main part (1), and fixed mounting has the drive structure on the top side inner wall of vacuum furnace main part (1), and the drive structure contacts with the fortune material structure.

2. The transport mechanism in a vacuum furnace and the vacuum furnace as claimed in claim 1, wherein: go up unloading structure trapped orbit (4), movable base plate (5), flexible bracing piece (6), installation box (7), the material bears frame (8), two trapped orbit (4) fixed mounting are subaerial, movable base plate (5) slidable mounting is in the top side of two fixed orbit (4), two flexible bracing piece (6) fixed mounting are in the top side of movable base plate (5), installation box (7) fixed mounting is in the top side of two flexible bracing pieces (6), two materials bear frame (8) fixed mounting on the side that installation box (7) are close to vacuum furnace main part (1).

3. The transport mechanism in a vacuum furnace and the vacuum furnace as claimed in claim 2, wherein: the top side of the movable base plate (5) is fixedly provided with a driving cylinder (9), and the output end of the driving cylinder (9) is fixedly arranged at the bottom side of the mounting box body (7).

4. The transport mechanism in a vacuum furnace and the vacuum furnace as claimed in claim 1, wherein: the base structure comprises fixed supporting feet (10) and fixed bases (11), the fixed bases (11) are symmetrically and fixedly installed on the inner wall of the bottom side of the vacuum furnace main body (1), and the fixed supporting feet (10) are fixedly installed at the top ends of the fixed bases (11).

5. The conveying mechanism in the vacuum furnace and the vacuum furnace as claimed in claim 4, wherein: the fixed base (11) is of a U-shaped structure, the concave surface end of the fixed base is positioned on the top side, and two fixed base adapting grooves (16) are formed in the fixed base (11).

6. The transport mechanism in a vacuum furnace and the vacuum furnace as claimed in claim 1, wherein: the material conveying structure comprises a sliding material seat (12), the vacuum furnace main body (1) is slidably mounted in a groove of a fixed base (11), two sliding material seat adaptation grooves (15) are formed in the sliding material seat (12), the two sliding material seat adaptation grooves (15) are communicated with two fixed base adaptation grooves (16), and the two sliding material seat adaptation grooves (15) and the two fixed base adaptation grooves (16) are matched with two material bearing frames (8).

7. The transport mechanism in a vacuum furnace and the vacuum furnace as claimed in claim 6, wherein: t-shaped sliding grooves (13) are formed in the inner walls of the two sides of the fixed base (11), T-shaped sliding blocks (14) are installed in the two T-shaped sliding grooves (13) in a rotating mode, and the two T-shaped sliding blocks (14) are fixedly installed on the two sides of the sliding material seat (12) respectively.

8. The transport mechanism in a vacuum furnace and the vacuum furnace as claimed in claim 1, wherein: the driving structure comprises a fixed mounting frame (17), material frame driving cylinders (18), driving rods (19) and connecting blocks (20), wherein the fixed mounting frame (17) is fixedly mounted on the top side of the vacuum furnace main body (1), the two material frame driving cylinders (18) are fixedly mounted on the same side face of the fixed mounting frame (17), the two connecting blocks (20) are fixedly mounted on the top side of the sliding material seat (12), one ends of the two driving rods (19) are respectively rotatably mounted on one side, far away from each other, of the two connecting blocks (20), and the other ends of the two driving rods (19) are respectively rotatably mounted on output ends of the two material frame driving cylinders (18).

9. The transport mechanism in a vacuum furnace and the vacuum furnace as claimed in claim 8, wherein: two drive holes (21) have all been seted up to the one end that actuating lever (19) are close to material frame drive actuating cylinder (18), all rotate in two drive holes (21) and install drive shaft (22), and two drive shaft (22) are fixed mounting respectively on the output of two fixed mounting brackets (17).

10. The transport mechanism in a vacuum furnace and the vacuum furnace as claimed in claim 8, wherein: connecting holes (23) are formed in the connecting blocks (20), connecting shafts (24) are rotatably mounted in the two connecting holes (23), and the two connecting shafts (24) are fixedly mounted on one side, close to the two driving rods (19), of each other respectively.

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