CN111203647A - High-speed precision laser galvanometer carving cutting machine - Google Patents

Abstract

The invention discloses a high-speed precise laser galvanometer engraving cutting machine, and belongs to the technical field of laser cutting machines. A high-speed precision laser galvanometer engraving cutting machine comprises an operation plate, wherein a conveying assembly is arranged on the operation plate and used for placing a piece to be engraved, the operation plate is fixedly connected with a laser cutting assembly, the high-speed precision laser galvanometer engraving cutting machine also comprises an air storage tank, a first sliding plate and a second sliding plate are connected in the air storage tank in a sliding mode, a telescopic assembly is fixedly connected onto the laser cutting assembly, a first connecting plate is fixedly connected onto the telescopic assembly, the first sliding plate is connected with the first connecting plate, and an upper air groove and a lower air groove are formed in the upper end and the lower end of the second sliding plate; the carving machine can carve a piece to be carved, can calibrate, position and fix the piece to be carved before carving, and can collect residual scraps after carving, so that the cutting effect is improved, the qualification rate of workpieces is improved, and the waste of resources is reduced.

Description

High-speed precision laser galvanometer carving cutting machine

Technical Field

The invention relates to the technical field of laser machines, in particular to a high-speed precise laser galvanometer engraving cutting machine.

Background

The cutting machine is divided into a flame cutting machine, a plasma cutting machine, a laser cutting machine, a water cutting machine and the like, the laser cutting machine has the fastest efficiency, the highest cutting precision and generally smaller cutting thickness, laser emitted from a laser device is focused into a laser beam with high power density through a light path system, the laser beam irradiates the surface of a workpiece to enable the workpiece to reach a melting point or a boiling point, meanwhile, high-pressure gas coaxial with the laser beam blows away molten or gasified metal, and part of the molten gasified metal falls onto the workpiece after being cooled by air, so that the workpiece needs to be manually cleaned, and the cleaning efficiency is slow.

During current laser cutting, place the work piece on the conveyer belt mostly, drive the work piece through the conveyer belt and remove, easy operation, work efficiency is fast, but when needing the cutting after the transportation, because the vibrations in the transportation, be not convenient for confirm and fix the position of work piece, and then make and make to make mistakes in the cutting position, and the work piece rocks in cutting process for cutting effect is not good, and the work piece percent of pass is low, resource-wasting.

Disclosure of Invention

The invention aims to solve the problems in the background technology, and provides a high-speed precise laser galvanometer engraving cutting machine.

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

a high-speed precise laser galvanometer engraving and cutting machine comprises an operation plate, wherein a transmission assembly is arranged on the operation plate and used for placing a piece to be engraved, the operation plate is fixedly connected with a laser cutting assembly, the gas storage tank is connected with a first sliding plate and a second sliding plate in a sliding manner, the laser cutting assembly is fixedly connected with a telescopic assembly, the telescopic assembly is fixedly connected with a first connecting plate, the first sliding plate is connected with the first connecting plate, the upper end and the lower end of the second sliding plate are provided with an upper gas groove and a lower gas groove, the upper gas groove and the lower gas groove are detachably connected through the connecting groove, a check valve is arranged in the connecting groove, a third connecting pipe is fixedly connected with the gas storage tank, the third connecting pipe is internally connected with a first check assembly, and a fourth connecting pipe is further connected with the third connecting pipe, one end of the fourth connecting pipe, which is far away from the third connecting pipe, is connected with the gas storage tank, a second one-way component is arranged on the fourth connecting pipe, the first one-way component is positioned between the joint of the fourth connecting pipe and the third connecting pipe and the gas storage tank, the operating plate is fixedly connected with a first fixing plate, the first fixing plate is provided with a third one-way component, a rotating shaft is fixedly connected on the first fixing plate, a pushing assembly is rotatably connected on the rotating shaft, the pushing component is provided with a resetting component, the first fixing plate is fixedly connected with an arc component through a second fixing plate, the two ends of the arc-shaped component are matched with the pushing component through the supporting columns, the arc-shaped component is fixedly connected with a second connecting pipe, the second connecting pipe and the first connecting pipe are communicated with the third connecting pipe, and the first connecting pipe and the pushing assembly are matched with the piece to be engraved.

Preferably, first one-way subassembly includes first baffle, first fixed block fixed connection is on the third connecting pipe, the first slip post of fixedly connected with on the first baffle, first slip post sliding connection is on first fixed block, the third spring has been cup jointed on the first slip post, the both ends of third spring fixed connection respectively are on first baffle, first slip post, be equipped with on the first fixed block with first baffle assorted air channel.

Preferably, the second unidirectional assembly comprises a second baffle plate, a return spring is sleeved on the second baffle plate, two ends of the return spring are respectively and fixedly connected to the second baffle plate and the gas storage tank, a connector matched with the second baffle plate is arranged on the gas storage tank, and the connector is matched with the fourth connecting pipe.

Preferably, the third one-way component comprises a third baffle and a third fixed block, the third fixed block is fixedly connected to the first connecting pipe, the third baffle is connected to the third fixed block in a sliding mode, and a reset piece is arranged on the third baffle.

Preferably, the arc assembly is a telescopic arc tube.

Preferably, the pushing assembly is a pushing expansion plate.

Preferably, a U-shaped elastic sheet is arranged between the two pushing expansion plates on the rotating shaft.

Preferably, the two pushing expansion plates on the rotating shaft are provided with torsion springs, and two ends of each torsion spring are respectively connected with the rotating shaft and the pushing expansion plate.

Preferably, a filter screen is arranged on the third connecting pipe and is located between the fourth connecting pipe and the first one-way component.

Preferably, the lower end of the second sliding plate is connected with a second spring, one end, far away from the second sliding plate, of the second spring is fixedly connected to the second sliding plate, a limiting block matched with the second sliding plate is arranged on the lower air groove, the first connecting plate is fixedly connected with a first spring, the other end of the first spring is fixedly connected with a second connecting plate, the second connecting plate is connected with the first sliding plate through a connecting column, and the bottom of the operation plate is fixedly connected with a supporting leg.

Compared with the prior art, the invention provides a high-speed precise laser galvanometer engraving cutting machine which has the following beneficial effects:

1. when the high-speed precise laser galvanometer engraving and cutting machine is used, a user can convey a workpiece to the lower end of a cutting head on a laser cutting assembly through a conveying assembly, the conveying assembly is fixedly connected to an operation plate, and the bottom of the operation plate is connected with a supporting leg, so that the stability of the operation plate is improved;

the telescopic component is a telescopic rod and drives the cutting head and the first connecting plate to move downwards, the first connecting plate moves downwards through the first spring and the second connecting plate and further drives the connecting column and the first sliding plate to move downwards, so that the upper gas groove is compressed and further drives the second sliding plate to move downwards and the second spring is compressed, the second sliding plate moves to the lower ends of the third connecting pipe and the fourth connecting pipe in a sliding manner, gas in the lower gas groove is reduced and enters the upper gas groove through the connecting groove, gas backflow can be prevented through the one-way valve, and the second sliding plate can be limited through the limiting block;

at the moment, the first sliding plate continues to move downwards, then the gas in the upper gas groove pushes the first baffle plate and the first sliding column to slide, the third spring is compressed, the second one-way component and the third one-way component are closed at the moment, further the gas enters the third connecting pipe and enters the telescopic arc-shaped plate through the second connecting pipe, so that the telescopic arc-shaped plate is extended, the pushing components are pushed to rotate, 8 pushing components rotate, further the carving piece to be positioned and fixed can be positioned and fixed, at the moment, in the cutting process, the first spring can play a role in buffering, and the pushing components are not easy to shake in the cutting process;

through promoting the subassembly for promoting the expansion plate, can be so that to collide mutually promoting the subassembly for the fixed effect that sculpture piece was treated to the promotion subassembly is better.

2. This high-speed accurate laser galvanometer sculpture cutting machine, after the sculpture is accomplished, flexible subassembly resets, the head of carving promptly shifts up, first connecting plate, the second connecting plate, the spliced pole, first sliding plate shifts up, under the effect of second spring, the second sliding plate shifts up, reset, the gas of gas inslot reduces down, under the atmospheric pressure effect, first one-way subassembly is closed, the one-way subassembly of second, the one-way subassembly of third is opened, at U type shell fragment, each promotion subassembly resets, and then through the third connecting pipe, first connecting pipe can absorb the remaining sweeps on treating the sculpture piece to the gas inslot down, make the gas groove through the spread groove, gas groove pressure is the same down, can carry out the cutting of next article, promptly:

the third baffle is opened, and the third baffle, the third fixed block of sweeps in the first connecting tube enter into the third connecting tube, are sifted through the filter screen, enter into the fourth connecting tube in, and second baffle, connector enter into the gas tank on the lower gas tank and store.

3. This high-speed accurate laser galvanometer sculpture cutting machine, both ends through the torsional spring are fixed connection respectively on axis of rotation, promotion expansion plate, and then are convenient for promote the reseing of expansion plate.

The part which is not involved in the device is the same as the prior art or can be realized by the prior art, the carving device can carve the piece to be carved, can calibrate, position and fix the piece to be carved before carving, and can collect residual scraps after carving, thereby improving the cutting effect, improving the qualification rate of the piece and reducing the waste of resources.

Drawings

FIG. 1 is a schematic structural diagram of a high-speed precision laser galvanometer engraving cutting machine according to the present invention;

FIG. 2 is a schematic structural diagram of a portion A in FIG. 1 of a high-speed precision laser galvanometer engraving cutting machine according to the present invention;

FIG. 3 is a schematic structural diagram of an air storage tank of the high-speed precise laser galvanometer engraving cutting machine provided by the invention;

FIG. 4 is a schematic structural diagram of a portion B in FIG. 3 of a high-speed precision laser galvanometer engraving cutting machine according to the present invention;

FIG. 5 is a schematic structural diagram of a high-speed precision laser galvanometer engraving cutting machine according to the present invention;

fig. 6 is a schematic structural diagram of a portion C in fig. 5 of a high-speed precision laser galvanometer engraving cutting machine according to the present invention.

In the figure: 1. an operating panel; 1001. a piece to be carved; 101. a transfer assembly; 102. a laser cutting assembly; 103. a telescoping assembly; 104. a first connecting plate; 105. a first spring; 106. a second connecting plate; 107. supporting legs; 2. a first fixing plate; 201. a second fixing plate; 202. an arc assembly; 2021. a second connecting pipe; 203. a support pillar; 204. a pushing assembly; 205. a rotating shaft; 206. a first connecting pipe; 207. a U-shaped elastic sheet; 3. a gas storage tank; 3001. an air feeding groove; 3002. a gas discharging groove; 301. connecting columns; 302. a first sliding plate; 303. a second sliding plate; 304. connecting grooves; 3041. a one-way valve; 305. a second spring; 306. a limiting block; 307. a third connecting pipe; 4. a first unidirectional component; 401. a first fixed block; 402. a first baffle plate; 403. a first sliding column; 404. a third spring; 5. a second unidirectional component; 501. a second baffle; 502. a fourth connecting pipe; 5021. a connecting port; 503. a filter screen; 6. a third baffle plate; 601. and a third fixed block.

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.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Example 1:

referring to fig. 1-6, a high-speed precision laser galvanometer engraving cutting machine, comprising an operation plate 1, wherein the operation plate 1 is provided with a transmission assembly 101, the transmission assembly 101 is used for placing a to-be-engraved element 1001, the operation plate 1 is fixedly connected with a laser cutting assembly 102, the high-speed precision laser galvanometer engraving cutting machine further comprises a gas storage tank 3, the gas storage tank 3 is slidably connected with a first sliding plate 302 and a second sliding plate 303, the laser cutting assembly 102 is fixedly connected with a telescopic assembly 103, the telescopic assembly 103 is fixedly connected with a first connecting plate 104, the first sliding plate 302 is connected with the first connecting plate 104, the upper end and the lower end of the second sliding plate 303 are provided with an upper gas tank 3001 and a lower gas tank 3002, the upper gas tank 3001 is detachably connected with the lower gas tank 3002 through a connecting tank 304, a one-way valve 3041 is arranged in the connecting tank 304, the gas storage tank 3 is fixedly connected with a third connecting pipe, one end of a fourth connecting pipe 502 far away from the third connecting pipe 307 is connected with the air storage tank 3, a second unidirectional assembly 5 is arranged on the fourth connecting pipe 502, a first unidirectional assembly 4 is positioned between the joint of the fourth connecting pipe 502 and the third connecting pipe 307 and the air storage tank 3, a first fixing plate 2 is fixedly connected on the operation plate 1, a third unidirectional assembly is arranged on the first fixing plate 2, a rotating shaft 205 is fixedly connected on the first fixing plate 2, a pushing assembly 204 is rotatably connected on the rotating shaft 205, a resetting assembly is arranged on the pushing assembly 204, an arc assembly 202 is fixedly connected on the first fixing plate 2 through a second fixing plate 201, two ends of the arc assembly 202 are matched with the pushing assembly 204 through a supporting column 203, a second connecting pipe 2021 and a second connecting pipe 2021 are fixedly connected on the arc assembly 202, the first connecting pipe 206 is communicated with the third connecting pipe 307, and the first connecting pipe 206 and the pushing assembly 204 are matched with the member to be engraved 1001.

First one-way component 4 includes first baffle 402, first fixed block 401 fixed connection is on third connecting pipe 307, first sliding column 403 of fixedly connected with on the first baffle 402, first sliding column 403 sliding connection is on first fixed block 401, third spring 404 has been cup jointed on first sliding column 403, the both ends of third spring 404 fixed connection respectively is on first baffle 402, first sliding column 403, be equipped with on first fixed block 401 with first baffle 402 assorted air channel.

The one-way subassembly 5 of second includes second baffle 501, has cup jointed reset spring on the second baffle 501, and reset spring's both ends are fixed connection respectively on second baffle 501, gas holder 3, be equipped with on the gas holder 3 with second baffle 501 assorted connector 5021, connector 5021 and fourth connecting pipe 502 phase-match.

The third unidirectional assembly comprises a third baffle 6 and a third fixing block 601, the third fixing block 601 is fixedly connected to the first connecting pipe 206, the third baffle 6 is slidably connected to the third fixing block 601, and a reset part is arranged on the third baffle 6.

The arc assembly 202 is a telescoping arc tube.

The pushing assembly 204 is a pushing expansion plate.

A U-shaped spring plate 207 is arranged between the two pushing expansion plates on the rotating shaft 205.

A filter screen 503 is disposed on the third connecting pipe 307, and the filter screen 503 is located between the fourth connecting pipe 502 and the first unidirectional assembly 4.

The lower end of the second sliding plate 303 is connected with a second spring 305, one end of the second spring 305, which is far away from the second sliding plate 303, is fixedly connected to the second sliding plate 303, a limiting block 306 matched with the second sliding plate 303 is arranged on the lower air groove 3002, the first spring 105 is fixedly connected to the first connecting plate 104, the other end of the first spring 105 is fixedly connected with a second connecting plate 106, the second connecting plate 106 is connected with the first sliding plate 302 through a connecting column 301, and the bottom of the operating plate 1 is fixedly connected with a supporting leg 107.

When a user uses the laser cutting assembly 102, a workpiece can be conveyed to the lower end of the cutting head on the laser cutting assembly 102 through the conveying assembly 101, the conveying assembly 101 is fixedly connected to the operation plate 1, and the bottom of the operation plate 1 is connected with the supporting leg 107, so that the stability of the operation plate 1 is improved, wherein the conveying assembly 101 and the laser cutting assembly 102 are the prior art and are not described in detail herein;

the telescopic assembly 103 is a telescopic rod and drives the cutting head and the first connecting plate 104 to move downwards, the first connecting plate 104 moves downwards through the first spring 105 and the second connecting plate 106 to further drive the connecting column 301 and the first sliding plate 302 to move downwards, so that the upper air groove 3001 is compressed, the second sliding plate 303 moves downwards and the second spring 305 is compressed, the second sliding plate 303 moves to the lower end of the third connecting pipe 307 and the lower end of the fourth connecting pipe 502 in a sliding manner, air in the lower air groove 3002 is reduced and enters the upper air groove 3001 through the connecting groove 304, the air can be prevented from flowing backwards through the one-way valve 3041, and the second sliding plate 303 can be limited through the limiting block 306;

at this time, the first sliding plate 302 continues to move downwards, and then the gas in the upper air groove 3001 pushes the first baffle 402 and the first sliding column 403 to slide, the third spring 404 is compressed, the second unidirectional component 5 and the third unidirectional component are closed at this time, so that the gas enters the third connecting pipe 307, and enters the telescopic arc-shaped plate through the second connecting pipe 2021, so that the telescopic arc-shaped plate is extended, the pushing component 204 is pushed to rotate, 8 pushing components 204 rotate, and further the carving piece 1001 to be positioned and fixed can be positioned and fixed, at this time, in the cutting process, the first spring 105 can play a role of buffering, so that the pushing component 204 is not easy to shake in the cutting process;

through pushing away subassembly 204 for promoting the expansion plate, can make and collide in pushing away subassembly 204 for pushing away subassembly 204 and treating the fixed effect of carving 1001 better.

Example 2:

referring to fig. 1-6, a high-speed precision laser galvanometer engraving cutting machine, which is substantially the same as the embodiment 1, further comprises:

after the sculpture is accomplished, flexible subassembly 103 resets, the head of carving moves up promptly, first connecting plate 104, second connecting plate 106, spliced pole 301, first sliding plate 302 moves up, under the effect of second spring 305, second sliding plate 303 moves up, reset, the gas in lower gas pocket 3002 reduces, under atmospheric pressure, first one-way subassembly 4 closes, second one-way subassembly 5, the one-way subassembly of third is opened, at U type shell fragment 207, each promotion subassembly 204 resets, and then can absorb the remaining sweeps on treating the sculpture 1001 to lower gas pocket 3002 in through third connecting pipe 307, first connecting pipe 206, make upper gas pocket 3001, lower gas pocket 3002 pressure the same through connecting groove 304, can carry out the cutting of next article, promptly:

the third baffle 6 is opened, the waste chips enter the third connecting pipe 307 through the third baffle 6 and the third fixing block 601 in the first connecting pipe 206, are screened by the filter screen 503 and enter the fourth connecting pipe 502, and the waste chips enter the lower air groove 3002 on the air storage tank 3 through the second baffle 501 and the connecting port 5021 for storage.

Example 3:

referring to fig. 1 to 6, a high-speed precision laser galvanometer engraving and cutting machine is substantially the same as that of embodiment 2, except that torsion springs are provided on two push retractable plates on a rotating shaft 205, and both ends of the torsion springs are respectively connected with the rotating shaft 205 and the push retractable plates.

The two ends of the torsion spring are respectively and fixedly connected to the rotating shaft 205 and the pushing expansion plate, so that the expansion plate can be conveniently pushed to reset.

The carving machine can carve the piece 1001 to be carved, can calibrate, position and fix the piece 1001 to be carved before carving, and can collect residual scraps after carving, so that the cutting effect is improved, the qualification rate of workpieces is improved, and the waste of resources is reduced.

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 high-speed precise laser galvanometer engraving and cutting machine comprises an operation plate (1), wherein a conveying assembly (101) is arranged on the operation plate (1), the conveying assembly (101) is used for placing a to-be-engraved element (1001), the laser cutting assembly (102) is fixedly connected to the operation plate (1), the high-speed precise laser galvanometer engraving and cutting machine is characterized by further comprising a gas storage tank (3), a first sliding plate (302) and a second sliding plate (303) are connected to the gas storage tank (3) in a sliding mode, a telescopic assembly (103) is fixedly connected to the laser cutting assembly (102), a first connecting plate (104) is fixedly connected to the telescopic assembly (103), the first sliding plate (302) is connected with the first connecting plate (104), an upper gas groove (3001) and a lower gas groove (3002) are arranged at the upper end and the lower end of the second sliding plate (303), and the upper gas groove (3001) is detachably connected with the lower gas groove (3002), a one-way valve (3041) is arranged in the connecting groove (304), a third connecting pipe (307) is fixedly connected to the gas storage tank (3), a first one-way component (4) is connected to the third connecting pipe (307), a fourth connecting pipe (502) is further connected to the third connecting pipe (307), one end, far away from the third connecting pipe (307), of the fourth connecting pipe (502) is connected to the gas storage tank (3), a second one-way component (5) is arranged on the fourth connecting pipe (502), the first one-way component (4) is located between the connecting position of the fourth connecting pipe (502) and the third connecting pipe (307) and the gas storage tank (3), a first fixing plate (2) is fixedly connected to the operating plate (1), a third one-way component is arranged on the first fixing plate (2), a rotating shaft (205) is fixedly connected to the first fixing plate (2), and a pushing component (204) is rotatably connected to the rotating shaft (205), be equipped with the subassembly that resets on promotion subassembly (204), first fixed plate (2) are through second fixed plate (201) fixedly connected with arc subassembly (202), the both ends of arc subassembly (202) all pass through support column (203) phase-match with promotion subassembly (204), fixedly connected with second connecting pipe (2021) on arc subassembly (202), second connecting pipe (2021), first connecting pipe (206) all communicate with each other with third connecting pipe (307), first connecting pipe (206), promotion subassembly (204) all with treat sculpture (1001) phase-match.

2. The high-speed precise laser galvanometer engraving and cutting machine according to claim 1, wherein the first unidirectional assembly (4) comprises a first baffle (402) and a first fixed block (401), the first fixed block (401) is fixedly connected to a third connecting pipe (307), a first sliding column (403) is fixedly connected to the first baffle (402), the first sliding column (403) is slidably connected to the first fixed block (401), a third spring (404) is sleeved on the first sliding column (403), two ends of the third spring (404) are respectively fixedly connected to the first baffle (402) and the first sliding column (403), and a ventilation groove matched with the first baffle (402) is formed in the first fixed block (401).

3. The high-speed precise laser galvanometer engraving and cutting machine according to claim 2, wherein the second unidirectional assembly (5) comprises a second baffle (501), a return spring is sleeved on the second baffle (501), two ends of the return spring are respectively and fixedly connected to the second baffle (501) and a gas storage tank (3), a connector (5021) matched with the second baffle (501) is arranged on the gas storage tank (3), and the connector (5021) is matched with a fourth connecting pipe (502).

4. The high-speed precise laser galvanometer engraving and cutting machine according to claim 1, wherein the third unidirectional assembly comprises a third baffle (6) and a third fixed block (601), the third fixed block (601) is fixedly connected to the first connecting pipe (206), the third baffle (6) is slidably connected to the third fixed block (601), and a reset piece is arranged on the third baffle (6).

5. The high-speed precision laser galvanometer engraving and cutting machine of claim 3, wherein the arcuate assembly (202) is a telescoping arcuate tube.

6. The high-speed precision laser galvanometer engraving and cutting machine of claim 4, wherein the pushing assembly (204) is a pushing expansion plate.

7. The high-speed precise laser galvanometer engraving and cutting machine according to claim 6, wherein a U-shaped elastic sheet (207) is arranged between the two pushing expansion plates on the rotating shaft (205).

8. The high-speed precise laser galvanometer engraving and cutting machine according to claim 6, wherein two pushing expansion plates on the rotating shaft (205) are provided with torsion springs, and two ends of each torsion spring are respectively connected with the rotating shaft (205) and the pushing expansion plate.

9. The high-speed precise laser galvanometer engraving and cutting machine according to claim 3, wherein a filter screen (503) is arranged on the third connecting pipe (307), and the filter screen (503) is positioned between the fourth connecting pipe (502) and the first unidirectional assembly (4).

10. The high-speed precise laser galvanometer engraving and cutting machine according to claim 9, wherein a second spring (305) is connected to the lower end of the second sliding plate (303), one end of the second spring (305) far away from the second sliding plate (303) is fixedly connected to the second sliding plate (303), a limiting block (306) matched with the second sliding plate (303) is arranged on the lower air groove (3002), a first spring (105) is fixedly connected to the first connecting plate (104), a second connecting plate (106) is fixedly connected to the other end of the first spring (105), the second connecting plate (106) is connected to the first sliding plate (302) through a connecting column (301), and a supporting leg (107) is fixedly connected to the bottom of the operating plate (1).

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