CN113275188B - Device for accelerating automatic deposition and film formation of nano silicon dioxide on surface of metal sheet - Google Patents

Abstract

The invention relates to the field of nano substances, in particular to a device for accelerating automatic deposition and film formation of silicon dioxide on the surface of a metal sheet. The invention aims to provide a film forming device for accelerating the automatic deposition of silicon dioxide on the surface of a metal sheet. The technical scheme is as follows: an automatic deposition film forming device for accelerating silicon dioxide on the surface of a metal sheet comprises a fixing frame, a controller, a conveying mechanism, a rotary leaching mechanism and an accelerated deposition film forming mechanism; the fixed frame is connected with the controller; the fixed frame is connected with the conveying mechanism; the fixed frame is connected with the rotary soaking mechanism; the fixed frame is connected with the accelerated deposition film-forming mechanism; the rotary dipping mechanism is connected with the deposition-accelerating film-forming mechanism. The invention can effectively accelerate the deposition and film formation of the nano silicon dioxide on the surface of the metal sheet, ensure the qualified quality of the metal sheet subjected to the deposition and film formation and effectively improve the production efficiency.

Description

Device for accelerating automatic deposition and film formation of nano silicon dioxide on surface of metal sheet

Technical Field

The invention relates to the field of nano substances, in particular to a device for accelerating automatic deposition and film formation of silicon dioxide on the surface of a metal sheet.

Background

The nano-substance is also called as a superfine substance material and consists of nano-particles. Nanoparticles, also called ultra-microparticles, generally refer to particles with a size between 1 and 100nm, which are transition regions between atomic clusters and macroscopic objects, and from the usual point of view regarding both the microscopic and macroscopic view, such systems are neither typical microscopic systems nor typical macroscopic systems, which are typical mesoscopic systems, having surface effects, small-size effects and macroscopic quantum tunneling effects. When a macroscopic object is subdivided into ultrafine particles, it will exhibit many unusual characteristics, namely its optical, thermal, electrical, magnetic, mechanical and chemical properties, which are significantly different than those of a bulk solid.

With the technological progress, nano-materials gradually enter the field of people, and are widely applied in the fields of various high-tech electronic products and the like, but with continuous exploration, scientists gradually discover that the nano-materials can not only be used in various high-end electronic products, but also have great effect on reinforcing the well wall of an oil drilling well, the existing well wall reinforcement adopts a self-assembly film technology, and insoluble substances dispersed in a solution are transferred to a solid support according to a certain arrangement mode to form a monomolecular layer or a plurality of parts of sub-layers of films, so that the aim of reinforcing the well wall is fulfilled.

Therefore, there is a need for an apparatus capable of accelerating the deposition of nano-silica on the surface of the raw material to form a film and ensuring the quality of the raw material for deposition to form a film.

Disclosure of Invention

The invention aims to overcome the defects that a large amount of time is consumed when nano silicon dioxide deposition film forming is carried out on the surface of a raw material, the whole period of each raw material is consumed for up to three days, the raw material cannot ensure that the surface of the raw material is completely deposited and formed into a film after deposition is finished, the insufficient deposition film forming on the surface of the raw material is possibly generated, the quality of a produced well wall support is not relevant, and great potential safety hazards are generated on the safety of workers and machines.

The technical scheme is as follows: an automatic deposition film-forming device for accelerating silicon dioxide on the surface of a metal sheet comprises a fixed frame, a controller, a conveying mechanism, a rotary leaching mechanism and an accelerated deposition film-forming mechanism; the fixed frame is connected with the controller; the fixed frame is connected with the conveying mechanism; the fixed frame is connected with the rotary soaking mechanism; the fixed frame is connected with the accelerated deposition film forming mechanism; the rotary dipping mechanism is connected with the deposition-accelerating film-forming mechanism.

As an improvement of the above scheme, the conveying mechanism comprises a first electric slider, a first U-shaped connecting plate, a second electric slider, a first transmission shaft, a first flat gear, a first connecting plate, a third electric slider, a first connecting column, a second connecting column, a first electric push rod, a second U-shaped connecting plate, a second transmission shaft, a second flat gear and a third flat gear; the first electric sliding block is in sliding connection with the fixed frame; the first electric sliding block is fixedly connected with the two groups of first U-shaped connecting plates; a group of first electric sliding blocks is arranged on both sides between the two groups of first U-shaped connecting plates; the first U-shaped connecting plate is in sliding connection with the two groups of second electric sliding blocks; the second electric slide block is rotationally connected with the first transmission shaft; the first transmission shaft is fixedly connected with the first flat gear; the first transmission shaft is fixedly connected with the first connecting plate; the first connecting plate is in sliding connection with the two groups of third electric sliding blocks; the second electric sliding block, the first connecting plate and the third electric sliding block are respectively provided with a group at two sides of the first U-shaped connecting plate; two groups of third electric sliding blocks are arranged on the two groups of first connecting plates; the first connecting column is fixedly connected with the other group of second electric sliding blocks; the first connecting column is rotatably connected with the second connecting column; the second connecting column is fixedly connected with the other group of first connecting plates; a group of second electric sliding blocks to a second connecting column is arranged on each of the two groups of first U-shaped connecting plates; a second flat gear is arranged above the first electric sliding block; the second flat gear is fixedly connected with a second transmission shaft; the second transmission shaft is rotationally connected with the second U-shaped connecting plate; the second transmission shaft is fixedly connected with the third flat gear; the second U-shaped connecting plate is fixedly connected with the first electric push rod; the first electric push rod is fixedly connected with the fixed frame.

As an improvement of the above scheme, the dip-coating mechanism includes a motor, a third transmission shaft, a first bevel gear, a second bevel gear, a fourth flat gear, a third bevel gear, a first sliding sleeve, a fourth transmission shaft, a second connecting plate, a second electric push rod, a first transmission wheel, a second transmission wheel, a fifth transmission shaft, a fifth flat gear, a fluted disc, a third connecting column, a disk, a first solution placing frame, a second solution placing frame, a protective plate, a waste liquid collecting frame, a nitrogen storing barrel, a third connecting plate, a first nitrogen conveying pipe, a first nitrogen outlet pipe, a sixth transmission shaft, a sixth flat gear, a fourth connecting plate, a fourth electric slider, a deionized water storing frame, a fifth electric slider, a sixth electric slider, a deionized water conveying pipe, a deionized water outlet pipe, a fourth connecting column, a fifth connecting column, a second nitrogen conveying pipe and a second nitrogen outlet pipe; the motor is fixedly connected with the fixing frame; the output shaft of the motor is fixedly connected with the third transmission shaft; the third transmission shaft is rotatably connected with the fixed frame; the third transmission shaft is fixedly connected with the first bevel gear, the second bevel gear and the fourth flat gear simultaneously; the first bevel gear is meshed with the accelerated deposition film forming mechanism; a third bevel gear is arranged above the second bevel gear; the third bevel gear is fixedly connected with the first sliding sleeve; the first sliding sleeve is connected with the fourth transmission shaft; the first sliding sleeve is rotatably connected with the second connecting plate; the fourth transmission shaft is rotatably connected with the fixed frame; the fourth transmission shaft is fixedly connected with the first transmission wheel; the second connecting plate is fixedly connected with the second electric push rod; the second electric push rod is fixedly connected with the fixing frame; the outer ring surface of the first driving wheel is in transmission connection with the second driving wheel through a belt; a fifth transmission shaft of the second transmission wheel is fixedly connected; the fifth transmission shaft is rotatably connected with the fixed frame; the fifth transmission shaft is fixedly connected with the fifth flat gear; the fifth flat gear is meshed with the fluted disc; the fluted disc is fixedly connected with the third connecting column; the third connecting column is rotatably connected with the fixing frame; the third connecting column is fixedly connected with the disc; the disc is fixedly connected with the two groups of third connecting plates through connecting blocks; a first solution placing frame is arranged below the disc; the first solution placing frame is fixedly connected with the fixing frame; the first solution placing frame is fixedly connected with the protection plate; a second solution containing frame is arranged on the side surface of the first solution containing frame; the second solution placing frame is fixedly connected with the fixing frame; the second solution placing frame is fixedly connected with the protection plate; a group of first solution placing frames and a group of second solution placing frames are arranged on the fixing frame at opposite angles; the protection plate is also provided with one group on the other group of the first solution placing frame and the second solution placing frame; a waste liquid collecting frame is arranged between the two groups of protection plates; the waste liquid collecting frame is fixedly connected with the fixing frame; the third connecting plate is fixedly connected with the nitrogen storage barrel; the third connecting plate is fixedly connected with the first nitrogen conveying pipe; the third connecting plate is rotatably connected with the sixth transmission shaft; the third connecting plate is fixedly connected with the second nitrogen conveying pipe; the first nitrogen conveying pipe is fixedly connected with a plurality of groups of first nitrogen outlet pipes; the sixth transmission shaft is fixedly connected with the sixth flat gear; the sixth transmission shaft is fixedly connected with the fourth connecting plate; the fourth connecting plate is in sliding connection with the fourth electric sliding block; the fourth electric slide block is fixedly connected with the deionized water storage frame; the fourth electric sliding block is simultaneously in sliding connection with the fifth electric sliding block and the sixth electric sliding block; the fourth electric slide block is fixedly connected with the deionized water conveying pipe; the deionized water storage frame is fixedly connected with the deionized water conveying pipe; a group of fifth electric sliding block and a group of sixth electric sliding block are arranged on both sides of the fourth electric sliding block; the deionized water delivery pipe is fixedly connected with a plurality of groups of deionized water outlet pipes simultaneously; a group of fourth connecting plates is arranged on both sides of the fourth electric sliding block; the other group of fourth connecting plates are fixedly connected with the fourth connecting columns; the fourth connecting column is rotatably connected with the fifth connecting column; the fifth connecting column is fixedly connected with the third connecting plate; a group of first nitrogen conveying pipe, a group of first nitrogen outlet pipe, a group of sixth transmission shafts, a group of sixth electric sliding blocks, a group of fourth connecting columns and a group of fifth connecting columns are arranged on two sides of a third connecting plate; the other two groups of fourth connecting plates are closer to the nitrogen storage barrel; the nitrogen storage barrel and the second nitrogen outlet pipe are respectively provided with a group at the opposite angle of the disc.

As an improvement of the above scheme, the deposition-accelerating and film-forming mechanism comprises a fourth bevel gear, a seventh transmission shaft, a third transmission wheel, a fourth transmission wheel, an eighth transmission shaft, a fifth bevel gear, a sixth bevel gear, a ninth transmission shaft, a second sliding sleeve, a seventh flat gear, a fifth connecting plate, a third electric push rod, a fifth transmission wheel, a sixth transmission wheel and a tenth transmission shaft; the fourth bevel gear is meshed with the first bevel gear; the fourth bevel gear is fixedly connected with a seventh transmission shaft; the seventh transmission shaft is rotationally connected with the fixed frame; the seventh transmission shaft is fixedly connected with the third transmission wheel and the fifth transmission wheel; the outer ring surface of the third driving wheel is in transmission connection with the fourth driving wheel through a belt; the fourth driving wheel is fixedly connected with the eighth transmission shaft; the eighth transmission shaft is rotatably connected with the fixed frame; the eighth transmission shaft is fixedly connected with the fifth bevel gear; the fifth bevel gear is meshed with the sixth bevel gear; the sixth bevel gear is fixedly connected with the ninth transmission shaft; the ninth transmission shaft is rotatably connected with the fixed frame; the ninth transmission shaft is connected with the second sliding sleeve; the second sliding sleeve is fixedly connected with the seventh flat gear; the second sliding sleeve is rotatably connected with the fifth connecting plate; the fifth connecting plate is fixedly connected with the third electric push rod; the third electric push rod is fixedly connected with the fixed frame; the outer ring surface of the fifth driving wheel is in transmission connection with the sixth driving wheel through a belt; the sixth transmission wheel is fixedly connected with the tenth transmission shaft; the tenth transmission shaft is rotatably connected with the fixed frame; a group of fifth bevel gears to a group of third electric push rods are also arranged at the opposite angles of the fixed frame; the tenth transmission shaft is fixedly connected with the other group of fifth bevel gears.

As an improvement of the above scheme, when the sixth flat gear and the other seventh flat gear are in the same inclined position, the two metal sheets clamped between the four groups of fifth electric sliding blocks and the sixth electric sliding blocks are just above the waste liquid collecting frame.

As an improvement of the scheme, the two groups of the first solution placing frames and the second solution placing frames are placed in a diagonal symmetry mode.

As the improvement of the scheme, cylindrical pressing blocks are arranged below the fifth electric sliding block and the sixth electric sliding block.

As an improvement of the scheme, a group of protection plates are respectively arranged on the two groups of first solution containing frames and the second solution containing frames.

The beneficial effects are that: 1. the method aims to overcome the defects that a large amount of time is consumed when nano silicon dioxide deposition film forming is carried out on the surface of a raw material, the whole period of each raw material consumes up to three days, the raw material cannot ensure that the surface is completely deposited and formed into a film after deposition is finished, the insufficient deposition and film forming on the surface of the raw material can be possibly caused, the quality of a produced well wall support is not too high, and great potential safety hazards are caused to the safety of workers and machines.

2. The invention designs a conveying mechanism, a rotary dipping mechanism and an accelerated deposition film-forming mechanism: before the work begins, the device is stably fixed through a fixing frame, then an external power supply is connected, two metal plates with the same size are placed on a conveying mechanism for the first time through manual work, the conveying mechanism fixes the two metal plates, then the conveying mechanism conveys the two metal plates to a first group of soaking parts of a rotary soaking mechanism, after the first group of soaking parts is fixed through the rotary soaking mechanism, the rotary soaking mechanism rotates one hundred and eighty degrees, a second group of soaking parts rotates to the same position of the first group, then the two metal plates with the same size are placed on the conveying mechanism again through manual work, then the conveying mechanism conveys the metal plates placed for the second time to a second group of soaking parts of the rotary soaking mechanism, the metal plates are fixed on the second group of soaking parts of the rotary soaking mechanism, then the rotary soaking mechanism simultaneously soaks the four metal plates into a first solution, and after soaking for a certain time, the rotary dipping mechanism rotates two groups of soaking parts by ninety degrees, then the rotary dipping mechanism simultaneously soaks four metal sheets into a second solution, after soaking for a certain time, the rotary dipping mechanism rotates two groups of soaking parts by a certain angle, so that the two groups of soaking parts of the rotary dipping mechanism are respectively positioned at the same inclined positions with two groups of inclined parts of the accelerated deposition film-forming mechanism, then the rotary dipping mechanism and the accelerated deposition film-forming mechanism work together to respectively incline the four metal sheets two by two, so as to accelerate the deposition film-forming of the surfaces of the four groups of metal sheets, after reciprocating for a certain number of times, the conveying mechanism overturns the metal sheets on the rotary dipping mechanism two by two at a time, namely the four metal sheets on the rotary dipping mechanism are all rotated by one hundred eighty degrees, then the other surfaces of the four metal sheets are subjected to accelerated deposition film-forming, and after the surface films of the four metal sheets are formed, the metal sheets are conveyed back to the original positions by the conveying mechanism by two at a time, and then removed manually.

3. The invention can effectively accelerate the deposition film formation of the nano silicon dioxide on the surface of the metal sheet, ensure the qualified quality of the metal sheet deposited with the film formation and effectively improve the production efficiency.

Drawings

FIG. 1 is a schematic perspective view of a first embodiment of the present invention;

FIG. 2 is a schematic perspective view of a second embodiment of the present invention;

FIG. 3 is a perspective view of the conveying mechanism of the present invention;

FIG. 4 is a perspective view of a portion of the conveying mechanism of the present invention;

FIG. 5 is a schematic perspective view of a rotary immersion mechanism according to the present invention;

FIG. 6 is a schematic view of a first partially assembled body structure of the transfer mechanism of the present invention;

FIG. 7 is a schematic view of a second partially-separated component of the rotary leaching apparatus of the present invention;

FIG. 8 is a perspective view of a third part of the rotary immersion mechanism of the present invention;

FIG. 9 is a perspective view of a fourth embodiment of the rotary immersion mechanism of the present invention;

FIG. 10 is a schematic perspective view of an accelerated deposition film-forming mechanism according to the present invention;

FIG. 11 is a schematic perspective view of a film formation mechanism with accelerated deposition according to the present invention.

Number designation in the figure: 1-a fixed frame, 2-a controller, 3-a conveying mechanism, 4-a rotary dipping mechanism, 5-an accelerated deposition film-forming mechanism, 301-a first electric slide block, 302-a first U-shaped connecting plate, 303-a second electric slide block, 304-a first transmission shaft, 305-a first flat gear, 306-a first connecting plate, 307-a third electric slide block, 308-a first connecting column, 309-a second connecting column, 3010-a first electric push rod, 3011-a second U-shaped connecting plate, 3012-a second transmission shaft, 3013-a second flat gear, 3014-a third flat gear, 401-a motor, 402-a third transmission shaft, a first bevel gear, 404-a second bevel gear, 405-a fourth flat gear, 406-a third bevel gear, 403-a first sliding sleeve, 408-a fourth transmission shaft, 409-a second connecting plate, 4010-a second electric push rod, 4011-a first transmission wheel, 4012-a second transmission wheel, 4013-a fifth transmission shaft, 4014-a fifth flat gear, 4015-a fluted disc, 4016-a third connecting column, 4017-a disc, 4018-a first solution placing frame, 4019-a second solution placing frame, 4020-a protective plate, 4021-a waste liquid collecting frame, 4022-a nitrogen gas storing barrel, 4023-a third connecting plate, 4024-a first nitrogen gas conveying pipe, 4025-a first nitrogen gas outlet pipe, 4026-a sixth transmission shaft, 4027-a sixth flat gear, 4028-a fourth connecting plate, 4029-a fourth electric slide block, 4030-a deionized water storing frame, 4031-a fifth electric slide block, 4032-a sixth electric slide block, 4033-deionized water conveying pipe, 4034-deionized water outlet pipe, 4035-fourth connecting column, 4036-fifth connecting column, 4037-second nitrogen conveying pipe, 4038-second nitrogen outlet pipe, 501-fourth bevel gear, 502-seventh transmission shaft, 503-third transmission wheel, 504-fourth transmission wheel, 505-eighth transmission shaft, 506-fifth bevel gear, 507-sixth bevel gear, 508-ninth transmission shaft, 509-second sliding sleeve, 5010-seventh flat gear, 5011-fifth connecting plate, 5012-third electric push rod, 5013-fifth transmission wheel, 5014-sixth transmission wheel and 5015-tenth transmission shaft.

Detailed Description

The above-described scheme is further illustrated below with reference to specific examples. It should be understood that these examples are for illustrative purposes and are not intended to limit the scope of the present application. The conditions used in the examples may be further adjusted according to the conditions of the particular manufacturer, and the conditions not specified are generally the conditions in routine experiments.

Example 1

An automatic deposition and film-forming device for accelerating silicon dioxide on the surface of a metal sheet is shown in figures 1-11 and comprises a fixed frame 1, a controller 2, a conveying mechanism 3, a rotary soaking mechanism 4 and an accelerated deposition and film-forming mechanism 5; the fixed frame 1 is connected with the controller 2; the fixed frame 1 is connected with the conveying mechanism 3; the fixed frame 1 is connected with the rotary soaking mechanism 4; the fixed frame 1 is connected with the accelerated deposition film-forming mechanism 5; the dipping mechanism 4 is connected with the deposition accelerating and film forming mechanism 5.

The working process is as follows: before the work begins, the device is stably fixed through the fixing frame 1, then the device is externally connected with a power supply, two metal plates with the same size are placed on the conveying mechanism 3 for the first time through manual work, the conveying mechanism 3 fixes the two metal plates, then the conveying mechanism 3 conveys the two metal plates to the first group of soaking parts of the rotary soaking mechanism 4, after the first group of soaking parts is fixed by the rotary soaking mechanism 4, the rotary soaking mechanism 4 rotates by one hundred eighty degrees, the second group of soaking parts rotates to the same positions of the first group, then the two metal plates with the same size are manually placed on the conveying mechanism 3 again, then the conveying mechanism 3 conveys the metal plates placed for the second time to the second group of soaking parts of the rotary soaking mechanism 4 and enables the metal plates to be fixed on the second group of soaking parts of the rotary soaking mechanism 4, then the rotary soaking mechanism 4 soaks the four metal plates into a first solution simultaneously, after soaking for a certain time, the rotary soaking mechanism 4 rotates two groups of soaking parts by ninety degrees, then the rotary soaking mechanism 4 simultaneously soaks four metal sheets into a second solution, after soaking for a certain time, the rotary soaking mechanism 4 rotates two groups of soaking parts by a certain angle, so that the two groups of soaking parts of the rotary soaking mechanism 4 are respectively positioned at the same inclined positions with two groups of inclined parts of the accelerated deposition film-forming mechanism 5, then the rotary soaking mechanism 4 and the accelerated deposition film-forming mechanism 5 work together to enable the four metal sheets to be respectively inclined two by two so as to accelerate the surface deposition film-forming of the four groups of metal sheets, after reciprocating for a certain number of times, the conveying mechanism 3 overturns the metal sheets on the rotary soaking mechanism 4 by two at a time, namely the four metal sheets on the rotary soaking mechanism 4 are all rotated by one hundred eighty degrees, and then the other surface of the four metal sheets is subjected to accelerated deposition film-forming, after the surface films of the four metal sheets are formed, the metal sheets are conveyed back to the original position by the conveying mechanism 3 two at a time, and then are taken away manually; the invention can effectively accelerate the deposition film formation of the nano silicon dioxide on the surface of the metal sheet, ensure the qualified quality of the metal sheet deposited with the film formation and effectively improve the production efficiency.

According to the invention, the conveying mechanism 3 comprises a first electric slider 301, a first U-shaped connecting plate 302, a second electric slider 303, a first transmission shaft 304, a first flat gear 305, a first connecting plate 306, a third electric slider 307, a first connecting column 308, a second connecting column 309, a first electric push rod 3010, a second U-shaped connecting plate 3011, a second transmission shaft 3012, a second flat gear 3013 and a third flat gear 3014; the first electric slide block 301 is connected with the fixed frame 1 in a sliding way; the first electric slide block 301 is fixedly connected with two groups of first U-shaped connecting plates 302; a group of first electric sliding blocks 301 are arranged on two sides between the two groups of first U-shaped connecting plates 302; the first U-shaped connecting plate 302 is in sliding connection with the two groups of second electric sliding blocks 303; the second electric slider 303 is rotatably connected with the first transmission shaft 304; the first transmission shaft 304 is fixedly connected with the first flat gear 305; the first transmission shaft 304 is fixedly connected with the first connecting plate 306; the first connecting plate 306 is connected with the two groups of third electric sliding blocks 307 in a sliding manner; a group of second electric sliding blocks 303, a group of first connecting plates 306 and a group of third electric sliding blocks 307 are arranged on two sides of the first U-shaped connecting plate 302; two groups of third electric sliding blocks 307 are arranged on the two groups of first connecting plates 306; the first connecting column 308 is fixedly connected with the other group of second electric sliding blocks 303; the first connecting column 308 is rotatably connected with the second connecting column 309; the second connecting column 309 is fixedly connected with the other group of first connecting plates 306; a group of second electric sliding blocks 303 to a second connecting column 309 are arranged on the two groups of first U-shaped connecting plates 302; a second flat gear 3013 is arranged above the first electric slider 301; the second flat gear 3013 is fixedly connected to the second transmission shaft 3012; the second transmission shaft 3012 is rotatably connected with the second U-shaped connecting plate 3011; the second transmission shaft 3012 is fixedly connected with the third flat gear 3014; the second U-shaped connecting plate 3011 is fixedly connected with the first electric push rod 3010; the first electric push rod 3010 is fixedly connected to the fixing frame 1.

Before the work begins, two identical metal sheets are manually placed between eight groups of third electric sliding blocks 307, then the eight groups of third electric sliding blocks 307 work simultaneously to clamp the two metal sheets respectively, then the two groups of first electric sliding blocks 301 drive the first U-shaped connecting plate 302 to the second connecting column 309 and the two metal sheets to move to the appointed position of the dip-transfer mechanism 4 simultaneously, then the two metal sheets are fixed by a first group of dip-transfer mechanism 4, then the four groups of second electric sliding blocks 303 drive the parts related to the first group of second electric sliding blocks to move downwards respectively until the third electric sliding blocks 307 are not blocked when returning to the original position, then the two groups of first electric sliding blocks 301 drive the first U-shaped connecting plate 302 to the second connecting column 309 to the original position, meanwhile the four groups of second electric sliding blocks 303 drive the parts related to the original position, then the dip-transfer mechanism 4 rotates one hundred eighty degrees, so that the second group of dip-transfer mechanism 4 moves to the same position as the first group of dip-transfer mechanism 309, then the four groups of second electric sliding blocks 301 are manually placed between the eight groups of third electric sliding blocks 307 again, and the fourth group of electric sliding blocks 309 are fixed to the electric sliding blocks 309, and the electric sliding blocks are repeatedly operated; the mechanism completes the conveying work of the metal sheet and the work of later metal sheet overturning.

The rotary immersion mechanism 4 comprises a motor 401, a third transmission shaft 402, a first bevel gear 403, a second bevel gear 404, a fourth flat gear 405, a third bevel gear 406, a first sliding sleeve 407, a fourth transmission shaft 408, a second connecting plate 409, a second electric push rod 4010, a first transmission wheel 4011, a second transmission wheel 4012, a fifth transmission shaft 4013, a fifth flat gear 4014, a fluted disc 4015, a third connecting column 4016, a circular disc 4017, a first solution placing frame 4018, a second solution placing frame 4019, a protective plate 4020, a waste liquid collecting frame 4021, a nitrogen storing barrel 4022, a third connecting plate 4023, a first nitrogen delivery pipe 4024, a first nitrogen outlet pipe 4025, a sixth transmission shaft 4026, a sixth flat gear 4027, a fourth connecting plate 4028, a fourth electric slider 4029, a deionized water storing frame 4030, a fifth electric slider 4031, a sixth electric slider 4032, a deionized water 4033, a deionized water delivery pipe 4034, a fourth flat gear 4025, a fourth connecting plate 4028, a fourth electric slider 4029, a fourth deionized water delivery pipe 4038, a fifth nitrogen outlet pipe 4038 and a nitrogen outlet pipe 4038; the motor 401 is fixedly connected with the fixing frame 1; an output shaft of the motor 401 is fixedly connected with a third transmission shaft 402; the third transmission shaft 402 is rotatably connected with the fixed frame 1; the third transmission shaft 402 is fixedly connected with a first bevel gear 403, a second bevel gear 404 and a fourth flat gear 405 at the same time; the first bevel gear 403 is meshed with the accelerated deposition film-forming mechanism 5; a third bevel gear 406 is arranged above the second bevel gear 404; the third bevel gear 406 is fixedly connected with the first sliding sleeve 407; the first sliding sleeve 407 is connected with the fourth transmission shaft 408; the first sliding sleeve 407 is rotatably connected with the second connecting plate 409; the fourth transmission shaft 408 is rotatably connected with the fixed frame 1; the fourth transmission shaft 408 is fixedly connected with the first transmission wheel 4011; the second connecting plate 409 is fixedly connected with a second electric push rod 4010; the second electric push rod 4010 is fixedly connected with the fixed frame 1; the outer ring surface of the first driving wheel 4011 is in driving connection with a second driving wheel 4012 through a belt; the fifth transmission shaft 4013 of the second transmission wheel 4012 is fixedly connected; the fifth transmission shaft 4013 is rotatably connected with the fixed frame 1; a fifth transmission shaft 4013 is fixedly connected with a fifth flat gear 4014; the fifth flat gear 4014 is meshed with a fluted disc 4015; the fluted disc 4015 is fixedly connected with a third connecting column 4016; the third connecting column 4016 is rotatably connected with the fixed frame 1; the third connecting column 4016 is fixedly connected with the disc 4017; the disc 4017 is fixedly connected with the two groups of third connecting plates 4023 through connecting blocks; a first solution placing frame 4018 is arranged below the disc 4017; the first solution placing frame 4018 is fixedly connected with the fixed frame 1; the first solution placing frame 4018 is fixedly connected with the protection plate 4020; a second solution placing frame 4019 is arranged on the side surface of the first solution placing frame 4018; the second solution placing frame 4019 is fixedly connected with the fixed frame 1; the second solution placing frame 4019 is fixedly connected with the protection plate 4020; a group of first solution placing frames 4018 and a group of second solution placing frames 4019 are arranged on opposite angles of the fixed frame 1; the protection plate 4020 is also provided with one group on the other group of the first solution placing frame 4018 and the second solution placing frame 4019; a waste liquid collecting frame 4021 is arranged between the two groups of protection plates 4020; the waste liquid collecting frame 4021 is fixedly connected with the fixing frame 1; the third connecting plate 4023 is fixedly connected with the nitrogen storage barrel 4022; the third connecting plate 4023 is fixedly connected with the first nitrogen conveying pipe 4024; the third connecting plate 4023 is rotatably connected with the sixth transmission shaft 4026; the third connecting plate 4023 is fixedly connected with a second nitrogen conveying pipe 4037; the first nitrogen conveying pipe 4024 is fixedly connected with a plurality of groups of first nitrogen outlet pipes 4025; a sixth transmission shaft 4026 is fixedly connected with a sixth flat gear 4027; the sixth transmission shaft 4026 is fixedly connected with the fourth connecting plate 4028; the fourth connecting plate 4028 is in sliding connection with a fourth electric slider 4029; the fourth electric sliding block 4029 is fixedly connected with the deionized water storage frame 4030; the fourth electric slider 4029 is simultaneously connected with the fifth electric slider 4031 and the sixth electric slider 4032 in a sliding manner; the fourth electric sliding block 4029 is fixedly connected with the deionized water conveying pipe 4033; the deionized water storage frame 4030 is fixedly connected with the deionized water conveying pipe 4033; a group of fifth electric slider 4031 and a group of sixth electric slider 4032 are arranged on both sides of the fourth electric slider 4029; the deionized water delivery pipe 4033 is fixedly connected with a plurality of groups of deionized water outlet pipes 4034 at the same time; a group of fourth connecting plates 4028 is arranged on both sides of the fourth electric slider 4029; the other group of fourth connecting plates 4028 is fixedly connected with the fourth connecting column 4035; the fourth connecting column 4035 is rotatably connected with the fifth connecting column 4036; the fifth connecting column 4036 is fixedly connected with the third connecting plate 4023; a first nitrogen delivery pipe 4024, a first nitrogen outlet pipe 4025, sixth transmission shafts 4026 to 4032, a fourth connecting column 4035 and a fifth connecting column 4036 are respectively provided with a group on two sides of the third connecting plate 4023; and the other two sets of fourth connector plates 4028 are closer to the nitrogen storage barrel 4022; the nitrogen gas storing buckets 4022 to the second nitrogen gas outlet pipe 4038 are provided in a group at opposite corners of the circular disk 4017.

When two metal sheets move to the positions right below the four groups of fifth electric sliding blocks 4031 and the sixth electric sliding blocks 4032 below the two groups of fourth electric sliding blocks 4029 respectively, the two groups of fourth electric sliding blocks 4029 simultaneously drive the parts related to the four groups of fourth electric sliding blocks 4031 and the sixth electric sliding blocks 4032 to move downwards until the four groups of fifth electric sliding blocks 4031 and the sixth electric sliding blocks 4032 cross the upper surfaces of the two metal sheets for a certain distance, then the four groups of fifth electric sliding blocks 4031 and the sixth electric sliding blocks 4032 simultaneously work to clamp the two metal sheets respectively, then the two groups of fourth electric sliding blocks 4029 simultaneously drive the parts related to the four groups of fourth electric sliding blocks to return to the original positions so as to ensure that the parts related to the conveying mechanism 3 cannot be blocked to return to the original positions, then the motor 401 starts to work, the motor 401 drives the third transmission shaft 402 to rotate, the third transmission shaft 402 drives the second bevel 401404 to rotate, the second electric push rod 0 drives the second connecting plate 409 to move downwards, namely, the third bevel gear 406 and the first sliding sleeve 407 move downwards, until the third bevel gear 406 is meshed with the second bevel gear 404, then the second bevel gear 404 drives the first sliding sleeve 407 through the third bevel gear 406, the first sliding sleeve 407 drives the fourth transmission shaft 408 to rotate, the fourth transmission shaft 408 drives the second transmission wheel 4012, the second transmission wheel 4012 drives the fifth flat gear 4014 through the fifth transmission shaft 4013, the fifth flat gear 4014 drives the third connecting column 4016 through the fluted disc 4015, the third connecting column 4016 drives the disc 4017 to rotate by one hundred eighty degrees, namely, the components related to the disc 4017 are driven to rotate by one hundred eighty degrees, so that the two groups of nitrogen storage barrels 4022 to 4036 exchange positions, then the two metal urination are conveyed to the lower parts of the four groups of fifth electric sliding blocks 4031 and sixth electric sliding blocks 4032 through the conveying mechanism 3, and then the nitrogen storage barrels 4022 to the fifth connecting column 4036 repeat the above operations, when the conveying mechanism 3 returns to the original position, the fourth electric slider 4029 drives the deionized water storage frame 4030 to the deionized water outlet pipe 4034 to move downwards, that is, drives the metal sheet clamped by the two groups of fifth electric sliders 4031 and the sixth electric slider 4032 to move downwards until the metal sheet is completely immersed in the first solution placement frame 4018, the metal sheets below the other three groups of fourth electric sliders 4029 complete the above work simultaneously, after the metal sheet is immersed in the first solution placement frame 4018 for a certain time, the fourth electric slider 4029 brings the relevant parts back to the original position, that is, the metal sheet is separated from the first solution placement frame 4018, then the motor 401 works again, and is engaged with the second bevel gear 404 through the third bevel gear 406 again to drive the relevant parts below the disc 4017 to rotate ninety degrees, that is, the four metal sheets respectively move to positions right above the two groups of second solution placement frames 4019, and then the four groups of fourth electric sliders 4029 work again, so that the four metal sheets are completely immersed in the two groups of second solution placing frames 4019, after soaking for a certain time, the fourth electric slide block 4029 brings back the relevant parts to the original positions again, i.e. the metal sheets are separated from the second solution placing frames 4019, then the motor 401 rotates the disc 4017 and the relevant parts below the disc 4017 through the third bevel gear 406 and the second bevel gear 404 at a certain angle, so that the four metal sheets are all positioned right above the waste liquid collecting frame 4021, the sixth flat gear 4027 is just at the same inclination angle with the deposition acceleration film forming mechanism 5, then the four metal sheets are all inclined at a certain angle through the deposition film forming mechanism 5, so as to accelerate the deposition film formation on the surface of the metal sheets, after the surface of the metal sheets are deposited for a certain time, the water pump in the deionized water storing frame 4030 starts to work, the water pump in the deionized water storing frame 4030 delivers the deionized water to the deionized water delivery pipe 4033, then deionized water is sprayed to the surface of the metal sheet through a plurality of groups of deionized water outlet pipes 4034 by a deionized water conveying pipe 4033, the surface of the metal sheet is easy to clean without adsorption deposition through the deionized water, then an air pump in a nitrogen storage barrel 4022 starts to work, the air pump in the nitrogen storage barrel 4022 conveys nitrogen to a first nitrogen conveying pipe 4024 and a second nitrogen outlet pipe 4038, the first nitrogen conveying pipe 4024 and the second nitrogen outlet pipe 4038 respectively blow the nitrogen to the surface of the metal sheet through a plurality of groups of second nitrogen conveying pipes 4037 and second nitrogen outlet pipes 4038, namely, the residual deionized water on the surface of the metal sheet is quickly cleaned through the nitrogen, the cleaned waste liquid automatically flows into a waste liquid collecting frame 4021, under the action of two groups of protective plates 4020, the waste liquid can be effectively prevented from flowing into two groups of first solution placing frames 4018 and second solution placing frames 4019, and the other group to the second nitrogen outlet pipes 4038 repeat the above work, then the motor 401 drives the disc 4017 to rotate again, so that the metal sheets move to the positions above the first solution placing frame 4018 and the second solution placing frame 4019 in turn, then the soaking and deposition film forming work is repeated for a certain number of times, that is, after the surface of the metal sheets is basically deposited to form a film, the fourth electric slider 4029 drives the metal sheets to move upward for a certain distance to ensure that the metal sheets do not obstruct the movement of the third electric slider 307, then the two groups of first electric sliders 301 drive the eight groups of third electric sliders 307 to move to the positions below the two corresponding metal sheets, the four groups of second electric sliders 303 drive the eight groups of third electric sliders 307 to move upward until the eight groups of third electric sliders 307 exceed the bottom of the metal sheets for a certain distance, then the eight groups of third electric sliders 307 clamp the two metal sheets, and simultaneously, the four groups of fifth electric sliders 4031 and the sixth electric slider 4032 loosen the two metal sheets, then two sets of fourth electric sliders 4029 drive four sets of fifth electric sliders 4031 and sixth electric sliders 4032 to move upwards until the metal sheets are not obstructed, then two sets of first electric sliders 301 drive the metal sheets to an initial placement position, then the first electric push rod 3010 drives the second U-shaped connecting plate 3011 to the third flat gear 3014 to move downwards until the third flat gear 3014 is meshed with the fourth flat gear 405, at the same time, the second flat gear 3013 is also meshed with two sets of first flat gears 305 at the same time, then the motor 401 drives the fourth flat gear 405 to rotate, the fourth flat gear 405 drives the second transmission shaft 3012 through the third flat gear 3014, the second transmission shaft 3012 simultaneously drives two sets of first flat gears 305 through the second flat gear 3013, and drives two sets of first transmission shafts 304 to rotate one hundred eighty degrees through two sets of first flat gears 305, the two metal sheets rotate one hundred eighty degrees, meanwhile, the two groups of first connecting columns 308 rotate around the two groups of second connecting columns 309 to ensure the stability of the device, then the two groups of first electric sliding blocks 301 work again to convey the metal sheets to the rotary dipping mechanism 4 after the metal sheets are placed initially, the other two metal sheets also work through the motor 401 to move to the same positions as the metal sheets to be turned, then the conveying mechanism 3 repeats the turning work of the metal sheets, the metal sheets after turning are conveyed to the initial placing positions through the rotary dipping mechanism 4 and the accelerated deposition film forming mechanism 5 again, after the surfaces of the metal sheets are completely deposited and formed into films, the metal sheets are conveyed to the initial placing positions through the conveying mechanism 3 in a group two by two, and then are taken away manually; the mechanism completes the soaking of the metal sheet and accelerates the deposition and film forming of the metal sheet surface main.

The accelerated deposition film-forming mechanism 5 comprises a fourth bevel gear 501, a seventh transmission shaft 502, a third transmission wheel 503, a fourth transmission wheel 504, an eighth transmission shaft 505, a fifth bevel gear 506, a sixth bevel gear 507, a ninth transmission shaft 508, a second sliding sleeve 509, a seventh flat gear 5010, a fifth connecting plate 5011, a third electric push rod 5012, a fifth transmission wheel 5013, a sixth transmission wheel 5014 and a tenth transmission shaft 5015; the fourth bevel gear 501 is meshed with the first bevel gear 403; a fourth bevel gear 501 is fixedly connected with a seventh transmission shaft 502; the seventh transmission shaft 502 is rotatably connected with the fixed frame 1; the seventh transmission shaft 502 is fixedly connected with the third transmission wheel 503 and the fifth transmission wheel 5013; the outer annular surface of the third driving wheel 503 is in driving connection with a fourth driving wheel 504 through a belt; the fourth driving wheel 504 is fixedly connected with an eighth transmission shaft 505; the eighth transmission shaft 505 is rotatably connected with the fixed frame 1; the eighth transmission shaft 505 is fixedly connected with the fifth bevel gear 506; the fifth bevel gear 506 meshes with the sixth bevel gear 507; a sixth bevel gear 507 is fixedly connected with a ninth transmission shaft 508; the ninth transmission shaft 508 is rotatably connected with the fixed frame 1; the ninth transmission shaft 508 is connected with the second sliding sleeve 509; the second sliding sleeve 509 is fixedly connected with a seventh flat gear 5010; the second sliding sleeve 509 is rotatably connected with the fifth connecting plate 5011; the fifth connecting plate 5011 is fixedly connected with a third electric push rod 5012; the third electric push rod 5012 is fixedly connected with the fixing frame 1; the outer ring surface of the fifth driving wheel 5013 is in transmission connection with a sixth driving wheel 5014 through a belt; the sixth transmission wheel 5014 is fixedly connected with a tenth transmission shaft 5015; the tenth transmission shaft 5015 is rotatably connected with the fixed frame 1; a group of fifth bevel gears 506 to a group of third electric push rods 5012 are also arranged at the opposite angles of the fixed frame 1; the tenth transmission shaft 5015 is fixedly connected to another set of fifth bevel gears 506.

When the four metal sheets move above the waste liquid collecting frame 4021, the sixth flat gear 4027 is just in the same inclined position as the seventh flat gear 5010, then the motor 401 drives the third transmission shaft 402 to rotate, the third transmission shaft 402 drives the fourth bevel gear 501 through the first bevel gear 403, the fourth bevel gear 501 drives the fourth transmission wheel 504 through the third transmission wheel 503, the fourth transmission wheel 504 drives the fifth bevel gear 506 through the eighth transmission shaft 505, the fifth bevel gear 506 drives the ninth transmission shaft 508 through the sixth bevel gear 507, the third electric push rod 5012 drives the fifth connecting plate 5011 to move close to the sixth flat gear 4027, namely, the second sliding sleeve 509 and the seventh flat gear 5010 are driven to move close to the sixth flat gear 4027 until the seventh flat gear 5010 is meshed with the sixth flat gear 4027, then the sixth bevel gear 507 drives the second sliding sleeve 509 through the ninth transmission shaft 508, the second sliding sleeve 509 drives a sixth flat gear 4027 through a seventh flat gear 5010, the sixth flat gear 4027 drives a sixth transmission shaft 4026 to rotate by a certain angle, the sixth transmission shaft 4026 drives a fourth connecting plate 4028 to a fourth connecting column 4035 and a metal sheet to rotate by a certain angle, the fourth connecting column 4035 ensures the stability of the device by rotating around a fifth connecting column 4036, meanwhile, the sixth flat gear 4027 drives another set of sixth flat gears 4027 engaged therewith to drive another metal sheet on the third connecting plate 4023 to rotate by a certain angle, so as to accelerate deposition on the surface of the metal sheet, similarly, the seventh transmission shaft 502 drives the fifth transmission wheel 5013 to rotate, the fifth transmission wheel 5013 drives the tenth 501transmission shaft 5 through a sixth transmission wheel 5014, another set of fifth bevel gears 506 of the tenth 5015 to rotate, and another set of fifth bevel gears 506 to third electric push rods 5012 repeat the above operations; the mechanism completes the work of accelerating the deposition and film formation on the surface of the metal sheet.

In the present invention, when the sixth flat gear 4027 and the other seventh flat gear 5010 are in the same inclined position, the two metal sheets clamped between the fourth group of fifth electric sliders 4031 and the sixth electric slider 4032 are both located just above the waste liquid collection frame 4021.

After the deposition on the surface of the metal sheet is accelerated, when the redundant solution is cleaned, the redundant solution can be collected through the waste liquid collecting frame 4021.

In the invention, two groups of the first solution containing frames 4018 and the second solution containing frames 4019 are diagonally and symmetrically arranged.

So that the metal sheets can be sequentially soaked in the solution in turn, and the speed of deposition and film formation is increased.

In the invention, cylindrical pressing blocks are arranged below the fifth electric sliding block 4031 and the sixth electric sliding block 4032.

The metal sheet is not affected while the metal sheet is clamped.

In the invention, two groups of first solution placing frames 4018 and second solution placing frames 4019 are respectively provided with a group of protection plates 4020.

Ensure that the washed waste liquid does not fall into both sets of the first solution placement box 4018 and the second solution placement box 4019.

Although embodiments of the present invention have been shown and described, it would be appreciated by those skilled in the art that changes may be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the claims and their equivalents.

Claims (5)

1. The utility model provides an accelerate sheet metal surface silica autodeposition film forming device, including mount H controller, characterized by: the device also comprises a conveying mechanism, a rotary soaking mechanism and an accelerated deposition film-forming mechanism; the fixed frame is connected with the controller; the fixed frame is connected with the conveying mechanism; the fixed frame is connected with the rotary soaking mechanism; the fixed frame is connected with the accelerated deposition film forming mechanism; the rotary leaching mechanism is connected with the accelerated deposition film-forming mechanism;

the conveying mechanism comprises a first electric slide block, a first U-shaped connecting plate, a second electric slide block, a first transmission shaft, a first flat gear, a first connecting plate, a third electric slide block, a first connecting column, a second connecting column, a first electric push rod, a second U-shaped connecting plate, a second transmission shaft, a second flat gear and a third flat gear; the first electric sliding block is in sliding connection with the fixed frame; the first electric slide block is fixedly connected with the two groups of first U-shaped connecting plates; a group of first electric sliding blocks is arranged on both sides between the two groups of first U-shaped connecting plates; the first U-shaped connecting plate is in sliding connection with the two groups of second electric sliding blocks; the second electric slide block is rotationally connected with the first transmission shaft; the first transmission shaft is fixedly connected with the first flat gear; the first transmission shaft is fixedly connected with the first connecting plate; the first connecting plate is in sliding connection with the two groups of third electric sliding blocks; the second electric slide block, the first connecting plate and the third electric slide block are respectively provided with a group at two sides of the first U-shaped connecting plate; two groups of third electric sliding blocks are arranged on the two groups of first connecting plates; the first connecting column is fixedly connected with the other group of second electric sliding blocks; the first connecting column is rotatably connected with the second connecting column; the second connecting column is fixedly connected with the other group of first connecting plates; a group of second electric sliding blocks to a second connecting column is arranged on each of the two groups of first U-shaped connecting plates; a second flat gear is arranged above the first electric sliding block; the second flat gear is fixedly connected with a second transmission shaft; the second transmission shaft is rotationally connected with the second U-shaped connecting plate; the second transmission shaft is fixedly connected with the third flat gear; the second U-shaped connecting plate is fixedly connected with the first electric push rod; the first electric push rod is fixedly connected with the fixing frame;

the rotary immersion mechanism comprises a motor, a third transmission shaft, a first bevel gear, a second bevel gear, a fourth flat gear, a third bevel gear, a first sliding sleeve, a fourth transmission shaft, a second connecting plate, a second electric push rod, a first transmission wheel, a second transmission wheel, a fifth transmission shaft, a fifth flat gear, a fluted disc, a third connecting column, a round disc, a first solution placing frame, a second solution placing frame, a protecting plate, a waste liquid collecting frame, a nitrogen storing barrel, a third connecting plate, a first nitrogen conveying pipe, a first nitrogen outlet pipe, a sixth transmission shaft, a sixth flat gear, a fourth connecting plate, a fourth electric sliding block, a deionized water storing frame, a fifth electric sliding block, a sixth electric sliding block, a deionized water conveying pipe, an outlet pipe, a fourth connecting column, a fifth connecting column, a second nitrogen conveying pipe and a second nitrogen outlet pipe; the motor is fixedly connected with the fixing frame; the output shaft of the motor is fixedly connected with the third transmission shaft; the third transmission shaft is rotationally connected with the fixed frame; the third transmission shaft is fixedly connected with the first bevel gear, the second bevel gear and the fourth flat gear at the same time; the first bevel gear is meshed with the accelerated deposition film-forming mechanism; a third bevel gear is arranged above the second bevel gear; the third bevel gear is fixedly connected with the first sliding sleeve; the first sliding sleeve is connected with the fourth transmission shaft; the first sliding sleeve is rotationally connected with the second connecting plate; the fourth transmission shaft is rotatably connected with the fixed frame; the fourth transmission shaft is fixedly connected with the first transmission wheel; the second connecting plate is fixedly connected with the second electric push rod; the second electric push rod is fixedly connected with the fixed frame; the outer ring surface of the first driving wheel is in transmission connection with the second driving wheel through a belt; a fifth transmission shaft of the second transmission wheel is fixedly connected; the fifth transmission shaft is rotatably connected with the fixed frame; the fifth transmission shaft is fixedly connected with the fifth flat gear; the fifth flat gear is meshed with the fluted disc; the fluted disc is fixedly connected with the third connecting column; the third connecting column is rotationally connected with the fixing frame; the third connecting column is fixedly connected with the disc; the disc is fixedly connected with the two groups of third connecting plates through connecting blocks; a first solution placing frame is arranged below the disc; the first solution placing frame is fixedly connected with the fixing frame; the first solution placing frame is fixedly connected with the protection plate; a second solution containing frame is arranged on the side surface of the first solution containing frame; the second solution placing frame is fixedly connected with the fixing frame; the second solution placing frame is fixedly connected with the protection plate; a group of first solution placing frames and a group of second solution placing frames are arranged on the fixing frame at opposite angles; the protection plate is also provided with one group on the other group of the first solution placing frame and the second solution placing frame; a waste liquid collecting frame is arranged between the two groups of protection plates; the waste liquid collecting frame is fixedly connected with the fixing frame; the third connecting plate is fixedly connected with the nitrogen storage barrel; the third connecting plate is fixedly connected with the first nitrogen conveying pipe; the third connecting plate is rotatably connected with the sixth transmission shaft; the third connecting plate is fixedly connected with the second nitrogen conveying pipe; the first nitrogen conveying pipe is fixedly connected with a plurality of groups of first nitrogen outlet pipes; the sixth transmission shaft is fixedly connected with a sixth flat gear; the sixth transmission shaft is fixedly connected with the fourth connecting plate; the fourth connecting plate is in sliding connection with the fourth electric sliding block; the fourth electric slide block is fixedly connected with the deionized water storage frame; the fourth electric sliding block is simultaneously in sliding connection with the fifth electric sliding block and the sixth electric sliding block; the fourth electric slide block is fixedly connected with the deionized water conveying pipe; the deionized water storage frame is fixedly connected with the deionized water conveying pipe; a group of fifth electric sliding block and a group of sixth electric sliding block are arranged on both sides of the fourth electric sliding block; the deionized water delivery pipe is fixedly connected with a plurality of groups of deionized water outlet pipes simultaneously; a group of fourth connecting plates is arranged on both sides of the fourth electric sliding block; the other group of fourth connecting plates are fixedly connected with the fourth connecting columns; the fourth connecting column is rotatably connected with the fifth connecting column; the fifth connecting column is fixedly connected with the third connecting plate; a group of first nitrogen conveying pipe, a group of first nitrogen outlet pipe, a group of sixth transmission shafts, a group of sixth electric sliding blocks, a group of fourth connecting columns and a group of fifth connecting columns are arranged on two sides of a third connecting plate; the other two groups of fourth connecting plates are closer to the nitrogen storage barrel; a group of nitrogen storage barrels and a group of second nitrogen outlet pipes are arranged at opposite angles of the circular disc;

the accelerated deposition film-forming mechanism comprises a fourth bevel gear, a seventh transmission shaft, a third transmission wheel, a fourth transmission wheel, an eighth transmission shaft, a fifth bevel gear, a sixth bevel gear, a ninth transmission shaft, a second sliding sleeve, a seventh flat gear, a fifth connecting plate, a third electric push rod, a fifth transmission wheel, a sixth transmission wheel and a tenth transmission shaft; the fourth bevel gear is meshed with the first bevel gear; the fourth bevel gear is fixedly connected with the seventh transmission shaft; the seventh transmission shaft is rotatably connected with the fixed frame; the seventh transmission shaft is fixedly connected with the third transmission wheel and the fifth transmission wheel; the outer ring surface of the third driving wheel is in transmission connection with the fourth driving wheel through a belt; the fourth driving wheel is fixedly connected with the eighth transmission shaft; the eighth transmission shaft is rotatably connected with the fixed frame; the eighth transmission shaft is fixedly connected with the fifth bevel gear; the fifth bevel gear is meshed with the sixth bevel gear; the sixth bevel gear is fixedly connected with the ninth transmission shaft; the ninth transmission shaft is rotationally connected with the fixed frame; the ninth transmission shaft is connected with the second sliding sleeve; the second sliding sleeve is fixedly connected with a seventh flat gear; the second sliding sleeve is rotatably connected with the fifth connecting plate; the fifth connecting plate is fixedly connected with a third electric push rod; the third electric push rod is fixedly connected with the fixing frame; the outer ring surface of the fifth driving wheel is in transmission connection with the sixth driving wheel through a belt; the sixth driving wheel is fixedly connected with the tenth transmission shaft; the tenth transmission shaft is rotationally connected with the fixed frame; a group of fifth bevel gears to a group of third electric push rods are also arranged at the opposite angles of the fixed frame; the tenth transmission shaft is fixedly connected with the other group of fifth bevel gears;

the first electric push rod drives the second U-shaped connecting plate to the third flat gear to move downwards until the third flat gear is meshed with the fourth flat gear, meanwhile, the second flat gear is also meshed with the two groups of first flat gears, then the motor drives the fourth flat gear to rotate, the fourth flat gear drives the second transmission shaft through the third flat gear, the second transmission shaft simultaneously drives the two groups of first flat gears through the second flat gear, and the two groups of first transmission shafts are driven to rotate by one hundred eighty degrees through the two groups of first flat gears;

the third electric push rod drives the fifth connecting plate to move towards the position close to the sixth flat gear, namely the second sliding sleeve and the seventh flat gear are driven to move towards the position close to the sixth flat gear until the seventh flat gear is meshed with the sixth flat gear, then the sixth bevel gear drives the second sliding sleeve through the ninth transmission shaft, and the second sliding sleeve drives the sixth flat gear through the seventh flat gear.

2. The apparatus according to claim 1, wherein when the sixth spur gear and the seventh spur gear are in the same inclined position, the two metal sheets clamped between the fifth electric slider and the sixth electric slider are located just above the waste liquid collecting frame.

3. The apparatus according to claim 2, wherein the two sets of the first solution containing frames and the second solution containing frames are disposed diagonally and symmetrically.

4. The apparatus according to claim 3, wherein a cylindrical pressing block is disposed below each of the fifth electric sliding block and the sixth electric sliding block.

5. An apparatus for accelerating the autodeposition of silica on a surface of a metal sheet into a film according to claim 4, wherein a set of shielding plates is provided on each of the two sets of first solution containing frames and second solution containing frames.

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