CN111151662A - Bilateral multiple spot synchronous mosaic device of thrust shoe - Google Patents

Abstract

The invention discloses a bilateral multipoint synchronous embedding device for a thrust tile, which comprises a bottom plate, two riveting mechanisms, second telescopic equipment, a riveting cutter and an extrusion mechanism, wherein the upper surface of the bottom plate is vertically provided with a fixing mechanism; the riveting mechanisms are symmetrically arranged on the left side and the right side of the fixing mechanism, each riveting mechanism comprises a sliding seat provided with a cavity, a sliding block and a mounting seat, the sliding seat is vertically connected with the bottom plate, the sliding block is connected in the cavity of the sliding seat in a sliding mode, the mounting seat is arranged on the surface of the sliding block, and at least one protection column is arranged on the surface of the sliding block; the second telescopic equipment pushes the sliding block to slide in the sliding seat cavity; at least one riveting cutter is arranged on the side wall of the mounting seat; the invention can complete multi-point synchronous inlaying of the tile seat and the tile body, has high installation efficiency and can well ensure the inlaying consistency of the thrust edges at two sides.

Description

Bilateral multiple spot synchronous mosaic device of thrust shoe

Technical Field

The invention relates to the field of bearing bush production and processing, in particular to a double-side multi-point synchronous inlaying device for a thrust bush.

Background

The bearing bush is a part of the sliding bearing, which is contacted with the journal, is in a bush-shaped semi-cylindrical surface, is very smooth, is generally made of wear-resistant materials such as bronze, antifriction alloy and the like, can be made of wood, engineering plastics or rubber under special conditions, has an integral type and a split type, is generally called as a shaft sleeve, has an oil groove or no oil groove, and is in clearance fit with the journal and generally does not rotate along with the shaft.

The bearing bush is used as one of important parts in an engine motion system, not only bears friction between a protective shaft and a seat hole, but also transmits motion load of the shaft, ensures that a crankshaft does not axially move when being subjected to axial thrust in the motion process in the operation process of the engine, enables a crank and a bush seat to have a good gap, and simultaneously enables a thrust plate not to damage the rotation direction of the crankshaft to rotate and fall off in the operation process.

The width of the integral flanging tile is fixed, so that the gap between the integral flanging tile and the tile seat and the gap between the integral flanging tile and the crank cannot be adjusted, and for a separated installation mode, the anti-thrust edge is easy to drop off in the assembling and using processes, a plurality of notches are formed in the edge of some tile bodies to install the anti-thrust edge, but no equipment can be used for riveting the tile seat and the tile body of the tile shaft in the prior art.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provides a double-side multi-point synchronous inlaying device for a thrust shoe, which can finish multi-point synchronous inlaying of a shoe seat and a shoe body, and after a thrust edge is inlaid on the shoe body, the thrust edge can move and can ensure the width of an inner stop between the two thrust edges, the moving amount of the thrust edge is 0.1-0.2 mm, the mounting efficiency is high, and the inlaying consistency of the thrust edges at two sides can be well ensured.

The invention is realized by the following technical scheme: the invention discloses a bilateral multipoint synchronous embedding device for a thrust tile, which comprises a bottom plate, two riveting mechanisms, second telescopic equipment, a riveting cutter and an extrusion mechanism, wherein the upper surface of the bottom plate is vertically provided with a fixing mechanism; the riveting mechanisms are symmetrically arranged on the left side and the right side of the fixing mechanism, each riveting mechanism comprises a sliding seat provided with a cavity, a sliding block and a mounting seat, the sliding seat is vertically connected with the bottom plate, the sliding block is connected in the cavity of the sliding seat in a sliding mode, the mounting seat is arranged on the surface of the sliding block, and at least one protection column is arranged on the surface of the sliding block; the second telescopic equipment pushes the sliding block to slide in the sliding seat cavity; at least one riveting cutter is arranged on the side wall of the mounting seat; the extrusion mechanism comprises a mounting frame, a pressing plate and first telescopic equipment, the mounting frame is fixedly connected with the first telescopic equipment, the pressing plate is driven by the first telescopic equipment to move up and down, and the pressing plate is arranged above the fixing mechanism and parallel to the upper side wall of the fixing mechanism.

When the inlaying device is installed, the positioning claw of the thrust edge is firstly clamped and fixed at the notch of the tile body, the positioning claw prevents the thrust edge from falling off, so that the thrust edge is arranged at the position of each of two side walls of the tile body, a workpiece which is preliminarily assembled is placed on the fixing mechanism, the fixing mechanism supports the workpiece which is preliminarily assembled, the thrust edge is in contact with the side wall of the female die to clamp the female die, and the inlaying device disclosed by the invention is started, wherein the working process of the inlaying device disclosed by the invention is as follows:

s100: a first lifting device in the extrusion mechanism drives a pressing plate to move downwards, the pressing plate contacts the upper end of a female die, the size of a groove body formed in the female die is the same as that of a tile body, and the tile body in the groove body of the female die cannot move at the moment;

s200: two riveting mechanisms work simultaneously, the second telescopic device pushes the sliding block to slide in the sliding seat cavity, the sliding seat drives the mounting seat to move, a riveting cutter is arranged on the mounting seat in a matched mode with the position of the notch in the tile body, the riveting cutter is in contact with the positioning claw and then extrudes the positioning claw, the positioning claw is bent, the anti-thrust edge and the tile body are riveted, and riveting consistency is kept.

Wherein, still be provided with the protection post perpendicularly on the slider, when protection post and slider contact, riveting cutter accomplishes the bending to the locating claw just, if there is not the protection post, riveting cutter probably acutely with the locating claw striking, thereby cause the damage of thrust limit and riveting cutter self, can dismantle the connection between protection post and the slider, the protection post also can set up to the elastic telescopic cylinder that has reset function, length shortens when the elastic telescopic cylinder is extrudeed, and the elastomeric element in the elastic telescopic cylinder cushions the power of slider, protect the slider, when the elastic telescopic cylinder is not extruded, the elastic telescopic cylinder resumes original length.

Preferably, in order to facilitate the separation of the riveted bearing bush from the female die, the fixing mechanism further comprises a driving device and a sliding device, the sliding device is slidably connected with the side wall of the female die, the driving device drives the sliding device to slide on the surface of the female die, after the riveting is completed, the driving device drives the sliding device to move upwards, and the sliding device pushes the riveted bearing bush to be separated from the female die through the extrusion of the thrust edge in the moving process.

Preferably, the sliding equipment comprises a frame body and block bodies, wherein at least two block bodies are fixedly arranged on the inner wall of the frame body, and through holes are formed in the block bodies;

the die surface has been seted up the spout, and the spout is inside to be provided with the slide bar, and block sliding connection slide bar, wherein, the setting of block and slide bar for gliding more stable.

Preferably, in order to prevent the sliding device from being blocked at a certain position of the sliding rod and being incapable of sliding downwards, and affecting the normal use of the sliding device, the surface of the sliding rod is sleeved with the elastic piece, the lower end of the elastic piece is contacted with the upper end of the block body, and the elastic piece applies downward force to the block body, so that the influence on the normal use of the sliding device due to the incapability of sliding normally of the sliding device is prevented.

Preferably, two lateral wall groove body edge position departments of die have at least one thickening plate detachably, the back on the tile body is inlayed to the thrust limit, the thrust limit both can move about, can guarantee the width of interior shelves between two thrust limits again, the momentum on thrust limit is between 0.1mm to 0.2mm, when the riveting, in order to prevent that the clearance between die and the thrust limit is too big, can reduce the clearance through the mode of installation thickening plate, the thickness of thickening plate is 0.1 mm.

Preferably, a plurality of thickened plates can be combined together for use, at least two convex blocks are arranged on the surface of one side of each thickened plate, a connecting groove is formed in the other side wall of each thickened plate and corresponds to the size and the position of each convex block, the thickened plates are connected with the connecting grooves or the convex blocks formed in the side walls of the female die through the convex blocks or the connecting grooves, the convex blocks of one thickened plate are embedded in the connecting grooves of the other thickened plate, the two thickened plates can be installed, and workers can adjust the number of the thickened plates according to the size of the gap between the female die and the thrust edge.

Preferably, the mounting seat comprises a plate body, and the plate body is detachably connected with the sliding block.

Preferably, in order to conveniently maintain and replace parts, the anti-thrust edge and the tile body provided with the positioning claws with different numbers can be installed, at least one installation groove is formed in the surface of the board body, the riveting cutter is embedded in the installation groove, and the position and the number of the riveting cutter are adjusted by a worker according to the number of the positioning claws on the anti-thrust edge to be riveted.

Preferably, in order to guarantee the stability of being connected between riveting cutter and the mounting groove, the riveting cutter bottom has seted up threaded hole, and the mounting groove has seted up spacing hole with the lateral wall of riveting cutter bottom contact, and threaded fastener passes mounting groove threaded connection screw hole.

Preferably, in order to enable the pressure plate to be stable in the moving process, at least one guide pillar is vertically arranged on the upper surface of the pressure plate, the guide pillar is connected with the mounting frame in an up-and-down sliding mode, and the arrangement of the guide pillar enables the pressure plate not to rotate in the moving process.

The invention discloses a bilateral multipoint synchronous inlaying device for a thrust shoe, which is compared with the prior art:

the invention can finish multi-point synchronous inlaying of the tile seat and the tile body, has high installation efficiency, can well ensure the inlaying consistency of the thrust edges at two sides, the first lifting device in the extrusion mechanism drives the pressing plate to move downwards, the pressing plate contacts the upper end of the female die, the size of the groove body formed by the female die is the same as that of the tile body, at the moment, the tile body in the groove body of the female die cannot move two riveting mechanisms to work simultaneously, the second telescopic device pushes the sliding block to slide in the cavity of the sliding seat, the sliding seat drives the installation seat to move, the positions of the notch on the tile body and the installation seat are provided with riveting tools in a matching way, after the riveting tools contact with the positioning jaws, the positioning jaws are extruded to bend, the thrust edges and the tile body are riveted, in order to conveniently maintain and replace parts, the thrust edges and the tile bodies with different numbers of positioning jaws can be installed, at least one, the riveting tool is embedded in the mounting groove, and the position and the number of the riveting tool are adjusted by workers according to the number of the positioning claws on the thrust edge to be riveted.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of a partial structure of the present invention after the extrusion mechanism is disassembled;

FIG. 3 is a schematic view showing the structure of the sliding apparatus according to the present invention;

FIG. 4 is a schematic view of the connection between the female die and the sliding device according to the present invention;

FIG. 5 is a front view of a female mold in the present invention;

FIG. 6 is a front view of a thickened plate according to the invention;

FIG. 7 is a top view of the mounting base of the present invention;

FIG. 8 is a front view of the riveting tool of the present invention;

FIG. 9 is a schematic view showing the structure of the pressing mechanism according to the present invention;

FIG. 10 is a schematic exterior view of the tile body;

fig. 11 is an external view of the thrust side.

In the figure: 1. an extrusion mechanism; 11. a mounting frame; 12. a guide post; 13. pressing a plate; 14. a first telescopic device; 2. a riveting mechanism; 21. a slide base; 22. a slider; 23. a mounting seat; 231. a plate body; 232. mounting holes; 233. mounting grooves; 234. a limiting hole; 24. a protective column; 3. a base plate; 4. a fixing mechanism; 41. a drive device; 42. a sliding device; 421. a slide base; 422. a block body; 423. a through hole; 43. a female die; 431. a chute; 432. a slide bar; 433. an elastic member; 44. thickening the plate; 5. a second telescopic device; 6. riveting a cutter; 61. a threaded hole; 91. a thrust edge; 911. a positioning claw; 92. a tile body; 921. and (4) a notch.

Detailed Description

The following examples are given for the detailed implementation and specific operation of the present invention, but the scope of the present invention is not limited to the following examples.

The invention discloses a bilateral multipoint synchronous inlaying device for a thrust tile, which comprises a bottom plate 3, two riveting mechanisms 2, a second telescopic device 5, a riveting cutter 6 and an extrusion mechanism 1, wherein the upper surface of the bottom plate 3 is vertically provided with a fixing mechanism 4, the fixing mechanism 4 comprises a female die 43 vertically connected with the bottom plate 3, the female die 43 is matched with a tile body 92 in size to form a groove body, and the fixing mechanism 4 supports the tile body 9; the two riveting mechanisms 2 are symmetrically arranged on the left side and the right side of the fixing mechanism 4, wherein the riveting mechanisms 2 comprise a sliding seat 21 provided with a cavity, a sliding block 22 and a mounting seat 23, the sliding seat 21 is vertically connected with the bottom plate 3, the sliding block 22 is slidably connected in the cavity of the sliding seat 21, the surface of the sliding block 22 is provided with the mounting seat 23, and the surface of the sliding block 22 is provided with at least one protective column 24; the second telescopic device 5 pushes the sliding block 22 to slide in the cavity of the sliding base 21; at least one riveting cutter 6 is arranged on the side wall of the mounting seat 23.

In order to facilitate the separation of the riveted bearing bush from the female die, the fixing mechanism 4 further comprises a driving device 41 and a sliding device 42, the sliding device 42 is slidably connected with the side wall of the female die 43, the driving device 41 drives the sliding device 42 to slide on the surface of the female die 43, wherein after the riveting is completed, the driving device 41 drives the sliding device 42 to move upwards, and the sliding device 42 pushes the riveted bearing bush to be separated from the female die 43 by pressing the anti-thrust edge 91 in the moving process. Preferably, in order to facilitate the separation of the riveted bearing bush from the die, the fixing mechanism 4 further comprises a driving device 41 and a sliding device 42, the sliding device 42 is slidably connected to the side wall of the die 43, the driving device 41 drives the sliding device 42 to slide on the surface of the die 43, wherein after the riveting is completed, the driving device 41 drives the sliding device 42 to move upwards, and the sliding device 42 pushes the riveted bearing bush to be separated from the die 43 by pressing the thrust edge 91 during the moving process.

As shown in fig. 3 and 4, the sliding device 42 includes a frame 421 and blocks 422, at least two blocks 422 are fixedly disposed on an inner wall of the frame 421, and through holes 423 are disposed on the blocks 422; the surface of the female die 43 is provided with a sliding groove 431, a sliding rod 432 is arranged inside the sliding groove 431, and the block 422 is slidably connected with the sliding rod 432, wherein the block 422 and the sliding rod 432 are arranged, so that the sliding is more stable.

In order to prevent the sliding device 42 from being blocked at a certain position of the sliding rod 432 and not sliding down, which affects the normal use of the invention, the surface of the sliding rod 432 is sleeved with the elastic member 433, the lower end of the elastic member 433 contacts the upper end of the block 422, and the elastic member 433 applies a downward force to the block 422, which prevents the normal use of the invention from being affected because the sliding device 42 cannot slide normally.

As shown in fig. 5, at least one thickened plate 44 is detachably mounted at the edge position of the groove body of the two side walls of the female die 43, after the thrust edge is embedded on the tile body, the thrust edge can move, the width of an inner stop between the two thrust edges can be ensured, the moving amount of the thrust edge is 0.1mm to 0.2mm, when riveting is performed, in order to prevent the overlarge gap between the female die 43 and the thrust edge 91, the gap can be reduced by mounting the thickened plate 44, and the thickness of the thickened plate 44 is 0.05 mm.

The surface of the thickened plate 44 is provided with a groove body, for two thickened plates 44, one end face of one thickened plate 44 can be connected with the other end face of the other thickened plate 44, wherein the connection mode can be that the surface of the female die 43 is provided with a threaded hole, a screw passes through a plurality of thickened plates 44 which are stacked together and provided with through holes, and the threaded hole is formed in the surface of the female die 43 through screw connection.

The present invention provides a detailed and specific scheme for connecting the thickened plates 44, as shown in fig. 6, a plurality of the thickened plates 44 can be combined together for use, at least two protrusions are arranged on one side surface of the thickened plates 44, and connecting grooves are arranged on the other side wall of the thickened plates 44 corresponding to the sizes and positions of the protrusions, wherein the thickened plates are connected with the connecting grooves or the protrusions arranged on the side wall of the female die 43 through the protrusions or the connecting grooves, the protrusions of one thickened plate 44 are embedded in the connecting grooves of the other thickened plate 44, so that the installation of the two thickened plates 44 can be completed, and the number of the thickened plates 44 can be adjusted by an operator according to the size of the gap between the female die 43 and the thrust edge 91.

As shown in fig. 7 and 8, the mounting seat 23 includes a plate 231, and the plate 231 is detachably connected to the slider 22.

In order to facilitate the maintenance and replacement of parts, the thrust edge 91 and the tile body 92 provided with the positioning claws 911 with different numbers can be installed, at least one installation groove 233 is formed in the surface of the board body 231, the riveting tool 6 is embedded in the installation groove 233, and the position and the number of the riveting tool 6 are adjusted by a worker according to the number of the positioning claws 911 on the thrust edge 91 to be riveted.

In order to ensure the stability of connection between riveting tool 6 and mounting groove 233, threaded hole 61 is opened at the bottom of riveting tool 6, limiting hole 234 is opened at the side wall of mounting groove 233 contacting with the bottom of riveting tool 6, and threaded fastener passes through mounting groove 233 and is in threaded connection with threaded hole 61.

As shown in fig. 9, the pressing mechanism 1 includes a mounting frame 11, a pressing plate 13 and a first telescopic device 14, the mounting frame 11 is fixedly connected to the first telescopic device 14, the first telescopic device 14 drives the pressing plate 13 to move up and down, the pressing plate 13 is arranged in parallel with the side wall of the fixing mechanism 4 directly above the fixing mechanism 4, in order to enable the pressing plate 13 to be stable in the moving process, at least one guide pillar 12 is vertically arranged on the upper surface of the pressing plate 13, the guide pillar 12 is connected to the mounting frame 11 in a vertically sliding manner, and the guide pillar 12 is arranged so that the pressing plate 13 cannot rotate in the moving process.

During installation, the positioning claws 911 of the thrust edge 91 are firstly clamped and fixed at the notches 921 of the tile body 92, because the positioning claws 911 prevent the thrust edge 91 from falling off, the thrust edges 91 are arranged at the positions of two side walls of the tile body 92, a workpiece which is preliminarily assembled is placed on the fixing mechanism 4, the fixing mechanism 4 supports the workpiece which is preliminarily assembled, wherein the thrust edge 91 contacts the side wall of the female die 43 to clamp the female die 743, and the inlaying device disclosed by the invention is started, and the working process of the inlaying device disclosed by the invention is as follows:

s100: the first lifting and contracting device 14 in the extrusion mechanism 1 drives the pressing plate 13 to move downwards, the pressing plate 13 contacts the upper end of the female die 43, the size of a groove body formed in the female die 43 is the same as that of the tile body 92, and the tile body 9 in the groove body of the female die 43 cannot move at the moment;

s200: two riveting mechanism 2 simultaneous workings, second telescoping device 5 promote slider 22 and slide in slide 21 cavity, and slide 21 drives mount pad 23 motion, and the position of breach 921 is paired with on tile body 92 on the mount pad 23 and is provided with riveting tool 6, and after riveting tool 6 contacted locating pawl 911, extrudeed locating pawl 911, made locating pawl 911 crooked, the riveting is accomplished to thrust limit 91 and tile body 92.

The slide block 22 is also vertically provided with a protection column 24, when the protection column 24 contacts with the slide block 22, the riveting tool 6 just bends the positioning claw 911, and if the protection column 24 is not provided, the riveting tool 6 may violently collide with the positioning claw 911, so that the thrust edge 91 and the riveting tool 6 are damaged.

It should be noted that the present invention does not specifically limit the structures of the first telescopic device 14, the second telescopic device 5 and the driving mechanism 41, these devices may be a cylinder, a hydraulic cylinder or a component driven by a lead screw, and any structure capable of implementing the corresponding functions is within the scope of the present application.

The invention does not limit the concrete structure of the elastic element, and the elastic element can be a spring, a sponge and the like.

In a specific embodiment provided by the invention, five mounting grooves 233 are formed on the surface of a plate 231, three of the five mounting grooves are provided with riveting tools 6, mounting holes 232 are further formed at the corners of the plate 231, threaded holes are formed at positions of a slider 22 corresponding to the mounting holes 232, the slider 22 is connected with the plate 231 through screws, the invention needs to rivet a tile body 92 in fig. 10 and a thrust edge 91 in fig. 11, three notches are respectively formed at two side walls of the tile body 92 in fig. 10, three positioning claws are arranged at the inner wall of the thrust edge 91 in fig. 11, the positioning claws 911 of the thrust edge 91 are clamped and fixed at the notches 921 of the tile body 92, because the positioning claws 911 prevent the thrust edge 91 from falling off, the thrust edge 91 is arranged at positions of the two side walls of the tile body 92, a primarily assembled workpiece is placed on a fixing mechanism 4, the fixing mechanism 4 supports the primarily assembled workpiece, wherein the thrust edge 91 contacts with the side wall of a female die 43 to clamp the female, when the riveting mechanism 2 works, the second telescopic device 5 pushes the sliding block 22 to slide in the cavity of the sliding base 21, the sliding base 21 drives the mounting base 23 to move, the three riveting tools 6 respectively contact the three positioning claws 911 to extrude the positioning claws 911, so that the positioning claws 911 are bent, and the anti-thrust edge 91 and the tile body 92 are riveted.

The invention is described above with reference to the accompanying drawings, it is obvious that the invention is not limited to the above embodiments, and it is within the scope of the invention to adopt various insubstantial modifications of the technical solution of the invention or to apply the concept and technical solution of the invention directly to other occasions without any modification.

Claims (10)

1. A thrust shoe bilateral multipoint synchronous embedding device is characterized by comprising:

the tile fixing device comprises a bottom plate, wherein a fixing mechanism is vertically arranged on the upper surface of the bottom plate, the fixing mechanism comprises a female die vertically connected with the bottom plate, the female die is matched with a tile body in size to form a groove body, and the fixing mechanism supports the tile body;

the riveting mechanisms are symmetrically arranged on the left side and the right side of the fixing mechanism, each riveting mechanism comprises a sliding seat provided with a cavity, a sliding block and a mounting seat, the sliding seat is vertically connected with the bottom plate, the sliding block is connected with the inside of the cavity of the sliding seat in a sliding manner, the surface of the sliding block is provided with the mounting seat, and the surface of the sliding block is provided with at least one protective column;

the second telescopic equipment pushes the sliding block to slide in the sliding seat cavity;

the side wall of the mounting seat is provided with at least one riveting cutter;

the extrusion mechanism comprises a mounting frame, a pressing plate and first telescopic equipment, the mounting frame is fixedly connected with the first telescopic equipment, the pressing plate is driven by the first telescopic equipment to move up and down, and the pressing plate is arranged right above the fixing mechanism and parallel to the upper side wall of the fixing mechanism.

2. The thrust shoe double-sided multipoint synchronous inlaying device of claim 1, wherein the fixing mechanism further comprises a driving device and a sliding device, the sliding device is slidably connected with the side wall of the female die, and the driving device drives the sliding device to slide on the surface of the female die.

3. The bilateral multipoint synchronous inlaying device for the thrust shoe as claimed in claim 2, wherein the sliding equipment comprises a frame body and block bodies, at least two block bodies are fixedly arranged on the inner wall of the frame body, and through holes are formed in the block bodies;

the die surface has been seted up the spout, the inside slide bar that is provided with of spout, just block sliding connection the slide bar.

4. The bilateral multipoint synchronous inlaying device for the thrust shoe as claimed in claim 3, wherein the surface of the sliding rod is sleeved with an elastic piece, and the lower end of the elastic piece is contacted with the upper end of the block body.

5. The thrust shoe double-sided multipoint synchronous embedding device as claimed in claim 4, wherein at least one thickened plate is detachably mounted at the edge position of the groove body on the two side walls of the female die.

6. The thrust shoe double-sided multipoint synchronous inlaying device of claim 5, wherein at least two protrusions are arranged on one side surface of the thickened plate, and connecting grooves are formed in the other side wall of the thickened plate and correspond to the protrusions in size and position.

7. The thrust shoe double-sided multipoint synchronous inlaying device of claim 1, wherein said mounting seat comprises a plate body, and said plate body is detachably connected with a sliding block.

8. The bilateral multipoint synchronous inlaying device for the thrust shoe as claimed in claim 7, wherein the surface of the plate body is provided with at least one mounting groove, and the riveting tool is inlaid in the mounting groove.

9. The thrust shoe bilateral multipoint synchronous inlaying device of claim 8, wherein the riveting tool is provided with a threaded hole at the bottom, the side wall of the mounting groove, which is in contact with the bottom of the riveting tool, is provided with a limiting hole, and the threaded fastener penetrates through the mounting groove to be in threaded connection with the threaded hole.

10. The thrust shoe double-sided multipoint synchronous inlaying device of claim 1, wherein at least one guide post is vertically arranged on the upper surface of the pressure plate, and the guide post is connected with the mounting frame in a vertically sliding manner.

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