CN115432940B - Production device and method of nano-film glass ink sheet for laser printing - Google Patents

Abstract

The invention provides a device for producing a nano-film glass ink sheet for laser printing, which comprises the following components: a base; the conveying mechanism comprises an annular track arranged on the upper surface of the base, a plurality of conveying blocks which are arranged on the annular track and can move along the annular track, and a supporting frame which is supported on the conveying blocks and is used for supporting a workpiece; the feeding mechanism is arranged at a feeding station on the base and used for feeding the workpiece to the supporting frame; the cleaner is arranged at a cleaning station on the base and is used for cleaning the upper surface of the workpiece on the support frame; the magnetron sputtering device is arranged at a magnetron sputtering station on the base and is used for sputtering required substances on the upper surface of the cleaned workpiece to obtain a nano film glass ink sheet; the blanking mechanism is arranged at a blanking station on the base and used for blanking the film-containing glass ink sheet on the support frame; a sealing cover; and (5) vacuumizing the device. The production device and the production method can simultaneously and circularly perform feeding, cleaning, titanium plating, copper plating and discharging, and have high production efficiency.

Description

Production device and method of nano-film glass ink sheet for laser printing

Technical Field

The invention relates to the field of production of nano film glass ink sheets, in particular to a device and a method for producing nano film glass ink sheets for laser printing.

Background

When the laser printing mode is adopted to perform additive manufacturing on the metal material, laser beams are controlled to be irradiated on the glass ink sheet covered with the metal coating with nano scale, so that the metal coating is melted and dropped to a required area and solidified and formed. For example, when the PCB with the open-circuit defect is repaired, the control system controls the laser to irradiate the nano film glass ink sheet, so that the copper material is melted and precisely dripped into the open-circuit defect area to fill the open-circuit defect area, and the circuit is connected.

There are various methods for preparing nano-coating ink sheet at present, for example, patent CN105274596a describes a method for preparing nano-copper coating by electrodeposition, and fully dense nano-material is prepared; CN113441711a describes a process for preparing nano copper with high oxidation resistance and high conductivity by using a modified nano copper technology with high conductivity and high weather resistance; CN102924996a describes a method for preparing nano copper ink and copper conductive film, by dispersing nano copper in ethanol, ethylene glycol or a mixed solution of ethanol and ethylene glycol containing short-chain hydroxycarboxylic acid, then coating it on the surface of a substrate, and roasting at low temperature to form the copper conductive film. The prior known technology does not relate to a production method and equipment for efficiently producing nano film glass ink sheets.

Disclosure of Invention

The invention mainly aims to provide a device and a method for producing nano-film glass ink sheet for laser printing,

in order to achieve the above purpose, the invention adopts the following technical scheme: a device for producing a nano-film glass ink sheet for laser printing comprises:

a base;

the conveying mechanism comprises an annular track arranged on the upper surface of the base, a plurality of conveying blocks which are arranged on the annular track and can move along the annular track, and a supporting frame which is supported on the conveying blocks and is used for supporting a workpiece;

the feeding mechanism is arranged at a feeding station on the base and used for feeding the workpiece to the supporting frame;

the plasma cleaner is arranged at a cleaning station on the base and is used for cleaning the upper surface of a workpiece on the support frame;

the first magnetron sputtering device is arranged at a first magnetron sputtering station on the base and is used for titanizing the upper surface of the cleaned workpiece;

the second magnetron sputtering device is arranged at a second magnetron sputtering station on the base and is used for copper plating the upper surface of the workpiece subjected to titanium plating to obtain a nano-film glass ink sheet;

the blanking mechanism is arranged at a blanking station on the base and used for blanking the film-containing glass ink sheet on the support frame;

the feeding station, the cleaning station, the first magnetron sputtering station, the second magnetron sputtering station and the discharging station are arranged along the annular track.

Preferably, a feeding cavity is formed in one side of the base, the feeding mechanism comprises a supporting plate which is arranged in the feeding cavity and can move up and down, the supporting plate is used for placing a glass substrate to be processed, and the supporting plate moves upwards for a preset height each time during feeding.

Preferably, the feeding mechanism further comprises four vertically arranged guide rods arranged around the supporting plate, and when the glass substrate is overlooked, the glass substrate can be just placed in a space surrounded by the guide rods, and the upper ends of the four guide rods penetrate out from the upper end opening of the feeding cavity.

Preferably, the feeding mechanism further comprises a conveying belt arranged right above the four guide rods, the conveying belt is arranged on the base through the mounting frame, the lower side portion of the conveying belt is horizontally arranged, the distance between the upper end of the guide rod close to the annular track and the lower surface of the lower side portion of the conveying belt is larger than the thickness of one glass substrate and smaller than the thickness of two glass substrates, and the distance between the upper ends of the other three guide rods and the lower surface of the lower side portion of the conveying belt is smaller than the thickness of one glass substrate.

Preferably, the feeding mechanism further comprises a linear module and a clamping mechanism arranged at the output end of the linear module, the moving direction of the output end of the linear module is parallel to the conveying direction of the conveying belt, two ends of the linear module extend to the position right above the annular track and the position right above the conveying belt respectively, and the clamping mechanism can clamp the glass substrate output by the conveying belt.

Preferably, the clamping mechanism comprises:

the vertical part is arranged at the output end of the linear module and can move up and down;

and the second clamping plate is horizontally arranged and is positioned right above the horizontal part, and the second clamping plate can move up and down relative to the first clamping plate so as to clamp or unclamp the glass substrate.

Preferably, the support frame comprises:

the supporting seat is arranged on the conveying block;

four support arms, set up the up end at the supporting seat, the one end setting of every support arm is in the up end of supporting seat, and the other end is towards the direction of keeping away from the supporting seat extension and adjacent support arm mutually perpendicular, is provided with the bar groove of arranging along its extending direction on every support arm, is provided with a positioning bolt on every bar groove, positioning bolt can round trip movement in the extending direction in bar groove and can realize positioning bolt's fixed through screwing up the nut on the positioning bolt, and positioning bolt on four support arms can enclose into the space of placing of glass substrate.

The invention also provides a production method of the nano-film glass ink sheet for laser printing, which adopts the production device and specifically comprises the following steps:

step S1: placing a glass substrate to be processed on a feeding mechanism, sealing by a sealing cover, and vacuumizing by a vacuumizing device;

step S2: the support frame moves to a feeding station, and the feeding mechanism moves the single glass substrate to the support frame;

step S3: the supporting frame moves to a cleaning station with the glass substrate, and the cleaner rapidly cleans the glass substrate after being fed;

step S4: the support frame moves to a magnetron sputtering station with the cleaned glass substrate, and one or more magnetron sputters uniformly sputter substances to the upper surface of the cleaned glass substrate in sequence to obtain the nano-film glass ink sheet;

step S5: the support frame moves to a blanking station with the obtained nano film glass ink sheet, and blanking is carried out on the nano film glass ink sheet obtained on the support frame;

the steps S2-S5 can be performed simultaneously, and the support frame can move among the feeding station, the cleaning station, one or more magnetron sputtering stations and the discharging station circularly and execute the steps S2-S5.

Compared with the prior art, the invention has the following beneficial effects:

the production device is provided with a feeding station, a cleaning station, a magnetron sputtering station and a discharging station, and when the support frame sequentially passes through the stations, feeding, cleaning, nano material uniform coating and discharging can be sequentially completed; the conveying rail of the production device is provided with a plurality of supporting frames, when one station is provided with the supporting frame, the other stations are also provided with the supporting frames, and the feeding, cleaning, titanium plating, copper plating and discharging can be simultaneously finished, so that the production efficiency is greatly improved; the conveying track of the production device is annular, and the supporting frame for completing the discharging from the discharging station directly enters the feeding station to carry out new-round production, so that the production efficiency is greatly improved.

Drawings

FIG. 1 is a perspective view of a preferred embodiment according to the present invention;

FIG. 2 is a block diagram of the seal housing of FIG. 1 with the seal housing removed;

FIG. 3 is an enlarged view at A;

fig. 4 is a structural view of the feeding mechanism;

fig. 5 is an enlarged view at B;

FIG. 6 is a block diagram of the clamping mechanism and the support frame;

fig. 7 is a block diagram of a support plate and its associated structure;

FIG. 8 is a schematic diagram of plasma cleaning;

fig. 9 is a schematic diagram of magnetron sputtering.

Description of the embodiments

The following description is presented to enable one of ordinary skill in the art to make and use the invention. The preferred embodiments in the following description are by way of example only and other obvious variations will occur to those skilled in the art.

As shown in fig. 1-7, a device for producing nano-film glass ink sheet for laser printing comprises a base 1, a feeding mechanism 5, a conveying mechanism 7, a plasma cleaner 10, a first magnetron sputtering device 8, a second magnetron sputtering device 9 and a discharging mechanism 6, wherein the feeding mechanism 5, the conveying mechanism 7, the plasma cleaner 10, the first magnetron sputtering device 9 and the discharging mechanism 6 are arranged on the base 1. The feeding mechanism 5 is arranged at the feeding station and is used for feeding the glass substrate to the conveying mechanism 7; the conveying mechanism 7 is used for driving the glass substrate to move; a plasma cleaner 10 is provided at the cleaning station for cleaning the glass substrate 100 on the conveyor 7; the first magnetron sputtering device 8 is arranged at the first magnetron sputtering station and is used for titanizing the glass substrate 100 on the conveying mechanism 7; the second magnetron sputtering device 9 is arranged at the second magnetron sputtering station and is used for carrying out copper plating on the glass substrate which is subjected to titanium plating on the conveying mechanism 7 to obtain a nano-film glass ink sheet; the blanking mechanism 6 is arranged at a blanking station and is used for blanking the nano film glass ink sheet manufactured on the conveying mechanism 7. The principles of plasma cleaning and magnetron sputtering may be employed in the prior art.

The conveying mechanism 7 includes an endless track 3 provided on the upper surface of the base 1, a plurality of conveying blocks 71 provided on the endless track 3 and movable along the endless track 3, and a support frame 4 for supporting a workpiece supported on the conveying blocks 71. The feeding station, the cleaning station, the first magnetron sputtering station, the second magnetron sputtering station and the discharging station are arranged around the annular track 3, and the supporting frame 4 sequentially passes through the stations to realize feeding, cleaning, titanizing, copper plating and discharging of the glass substrate. The support frame 4 can circulate the station along the annular track 3, and after the support frame 4 passes through the blanking station, the support frame directly enters the loading station to carry new glass substrates to finish processing until all the glass substrates are finished processing. At least five supporting frames 4 are arranged on the annular track 3, the at least five supporting frames 4 synchronously move along the annular track 3, when one station is provided with the supporting frames 4, the other stations are respectively provided with one supporting frame 4, namely, corresponding actions can be synchronously completed at the five stations, namely, different glass substrates can be simultaneously fed, cleaned, titanized and plated with copper. Preferably, the distance of each movement of the support frame 4 is the length of the endless track divided by the number of support frames 4, and the distance of adjacent stations along the conveying direction of the conveying mechanism 7 is equal to an integer multiple of the distance of each movement of the support frame 4.

The feeding mechanism 5 is used for feeding the glass substrate 100, a feeding cavity 515 is disposed at one side of the base 1, the feeding mechanism 5 includes a support plate 513 disposed in the feeding cavity 515 and capable of moving up and down, the support plate 513 is used for placing the glass substrate 100 to be processed, and during feeding, the support plate 513 moves up by a predetermined height each time, preferably, the predetermined height is the thickness of the glass substrate 100.

The feeding mechanism 5 further comprises four vertically arranged guide rods 514 arranged around the supporting plate 513, and when seen from top, the glass substrate can be just placed into the space surrounded by the guide rods 513 and each guide rod 514 abuts against the middle position of the corresponding side of the glass substrate. The upper ends of the four guide rods 514 penetrate out from the upper end openings of the feeding chambers 515.

The feeding mechanism 5 further comprises a conveying belt 52 arranged right above the four guide rods 514, and the conveying belt 52 is arranged on the base 1 through the mounting frame 55. The lower part of the conveyor belt 52 is horizontally arranged, and the distance between the upper end of the guide rod 514, which is close to the circular track 3, and the lower surface of the lower part of the conveyor belt 51 is greater than the thickness of one glass substrate 100 and less than the thickness of two glass substrates, namely, only one glass substrate 100 can be output at a time; the upper ends of the other three guide rods 514 are spaced from the lower surface of the lower portion of the conveyor belt 51 by a distance smaller than the thickness of one glass substrate 100, i.e., the glass substrate 100 cannot be output in the direction of the other three guide rods 514.

The feeding mechanism 5 further comprises a linear module 53 and a clamping mechanism 54 arranged on the output end of the linear module 53, the moving direction of the output end of the linear module 53 is parallel to the conveying direction of the conveying belt 51, two ends of the linear module 53 respectively extend to the position right above the annular track 3 and the position right above the conveying belt 51, the clamping mechanism 54 can clamp the glass substrate 100 output by the conveying belt 51, and after clamping the glass substrate 100, the linear module 53 drives the glass substrate 100 to move to the position right above the annular track 3, so that the glass substrate 100 can be placed on the supporting frame 4.

The clamping mechanism 54 includes a first clamping plate 542 and a second clamping plate 543 movable up and down relative to the first clamping plate 542, the first clamping plate 542 includes a vertical portion and a horizontal portion provided at a lower end of the vertical portion, the second clamping plate 543 is horizontally disposed and located right above the horizontal portion, and the second clamping plate 543 can be moved up and down relative to the horizontal portion so as to be capable of clamping or unclamping a glass substrate. Preferably, the second clamping plate 543 is driven by a second cylinder provided on the vertical portion. The first clamping plate 542 can move up and down, and the first clamping plate 542 is driven by a first cylinder 542 provided at the output end of the linear module 53. Rubber pads are provided on the clamping surfaces of the first clamping plate 542 and the second clamping plate 543 to play a role of buffering.

The support frame 4 comprises a support seat 41 arranged on the conveying block 71 and four support arms 42 arranged on the upper end face of the support seat 41, one end of each support arm 42 is arranged on the upper end face of the support seat 41, the other end extends towards the direction far away from the support seat 41, and the adjacent support arms 42 are mutually perpendicular. A bar groove 43 is provided on each support arm 42 along the extending direction thereof, a positioning bolt 44 is provided on each bar groove 43, the positioning bolt 44 can be moved back and forth in the extending direction of the bar groove 43 and fixation of the positioning bolt 44 can be achieved by tightening nuts on the positioning bolt 44, the positioning bolts 44 of the four support arms 42 can enclose a placing space of the glass substrate 100, and the four positioning bolts 44 can be adjusted for the glass substrates 100 of different sizes.

During feeding, one end of the uppermost glass substrate 100 is pushed out by the conveyor belt 51 for a certain distance, but the other end is still clamped between the conveyor belt 51 and the next glass substrate 100, and the linear module 53 drives the clamping mechanism 54 to move towards the glass substrate 100 and clamp the glass substrate 100; then, the linear module 53 retreats while the conveyor belt 51 conveys the glass substrate 100 in a direction in which the glass substrate 100 is pushed out; finally, the linear module 53 moves the glass substrate 100 onto the support frame 4 at the loading station.

Preferably, in order to be able to adapt to glass substrates 100 of different sizes, the four guide bars 513 may also be in the form of bar-shaped grooves, so that their relative positions may be changed.

A blanking cavity is arranged on the base 1 and corresponds to the position of the blanking mechanism 6, and a part of the blanking mechanism 6 is arranged in the blanking cavity. The blanking mechanism 6 is approximately the same as the feeding mechanism 5 in structure, but a conveying belt is not needed, during blanking, the clamping mechanism clamps the thin film glass ink containing sheet located at the blanking station, the linear module drives the clamping mechanism to move to the position right above the supporting plate, the thin film glass ink containing sheet to be placed is lower than the upper end of the guide rod through downward movement, and when the linear module drives the clamping mechanism to retract, the guide rod can prevent the thin film glass ink containing sheet from retracting and then falling onto the supporting plate or other thin film glass ink containing sheets already placed on the supporting plate. Each time a nano-film glass ink sheet is placed, the support plate is lowered by the thickness distance of one nano-film glass ink sheet. The first cylinder of the blanking mechanism 6 can be replaced by a motor and a screw rod.

Preferably, the production apparatus further comprises a sealing cover 2 covering the upper surface of the base 1, and the sealing cover 2 can ensure a closed environment and can vacuum the inner space. The base 1 is provided with openings at positions corresponding to the feeding cavity and the discharging cavity, the openings are provided with doors 516 for plugging or opening the openings, and the doors 516 facilitate corresponding operation of the feeding cavity and the discharging cavity. Preferably, the evacuation device is also connected to the inside through one of the doors 516, which reduces the number of openings in the base 1, and the door 516 can be provided to be removable.

In practical use, one or more than two magnetron sputterers can be arranged, and the magnetron sputterers can also sputter titanium and copper, and can sputter silver, zinc and the like, so that the production or processing of different products can be realized in a sputtering mode. For example:

case 1: uniformly plating a silver layer with the thickness of 20-80nm on a glass substrate with the thickness of 20mm and 100mm and 3mm, and then uniformly plating a copper layer with the thickness of 100-300nm for laser repair of a PCB circuit board;

case 2: uniformly plating a silver layer with the thickness of 30-100nm on a glass substrate with the diameter of 50.8mm and the thickness of 0.3mm, and then uniformly plating a titanium layer with the thickness of 100-500nm for laser 3D printing parts;

case 3: a zinc layer with the thickness of 20-100nm is uniformly plated on a glass substrate with the thickness of 10mm and 50mm and 1mm, and then a nickel layer with the thickness of 100-500nm is uniformly plated for laser repair of parts.

Examples

The embodiment is a method for producing nano film glass ink sheet by adopting the production device in the first embodiment, which specifically comprises the following steps:

step S1: placing a plurality of glass substrates 100 on a support plate 513 of the loading mechanism 5;

step S2: covering the sealed cover 2, and vacuumizing the sealed cover 2 by a vacuumizing device;

step S3: the supporting plate 513 is lifted a certain distance;

step S4: the conveyor belt 52 rotates to move the uppermost glass substrate 100 a distance toward the clamping mechanism 54;

step S5: the linear module 53 moves to a position where the substrate 100 is peeled with the holding mechanism 54, and the holding mechanism 54 holds the peeled substrate 100;

step S6: the linear module 53 moves in the opposite direction with the clamping mechanism 54, so that the glass substrate on the clamping mechanism 54 moves to the position right above the supporting frame 4 positioned at the feeding station;

step S7: the gripping mechanism 54 moves downward to place the peeled substrate 100 on the supporting frame 4;

step S8: the clamping mechanism 54 moves upward;

step S9: the conveying mechanism 7 drives the supporting frame 4 to move to a cleaning station, and the plasma cleaner 10 cleans the upper surface of the glass substrate;

step S10: after cleaning is completed, the conveying mechanism 7 drives the glass substrate to move to a first magnetron sputtering station for titanizing;

step S11: after the titanium plating is completed, the conveying mechanism 7 drives the glass substrate to move to a second magnetron sputtering station for copper plating;

step S12: after copper plating is completed, the conveying mechanism 7 drives the glass substrate to move to a blanking station for blanking, and the nano-film glass ink sheet is obtained.

In actual production, support frame 4 has a plurality ofly, and different support frames 4 can remove a plurality of glass substrates to material loading station, clean station, first magnetron sputtering station, second magnetron sputtering station and unloading station simultaneously, can carry out material loading, clean, titanium plating, copper plating and unloading processing simultaneously. Moreover, the conveying mechanism 7 is annular, the supporting frame 4 can circulate through the stations, and in the production process, normal production can be realized by only ensuring that the conveying mechanism 7 always drives the supporting frame along the conveying direction, so that the production efficiency is further improved. Of course, the magnetron sputtering station may have one or more than two to accomplish sputtering of different materials.

In steps S10 and S11, the thickness of sputtering and the number of times of sputtering may be determined according to actual conditions. The sputtering material may be changed as needed, and may be silver, zinc, or the like, for example. Meanwhile, the number of sputtering stations can be increased or reduced so as to adapt to different processing requirements.

The foregoing has shown and described the basic principles, principal features and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present invention, and various changes and modifications may be made therein without departing from the spirit and scope of the invention, which is defined by the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (9)

1. The device for producing the nano-film glass ink sheet for laser printing is characterized by comprising the following components:

a base;

the conveying mechanism comprises an annular track arranged on the upper surface of the base, a plurality of conveying blocks which are arranged on the annular track and can move along the annular track, and a supporting frame which is supported on the conveying blocks and is used for supporting a workpiece, wherein the supporting frame is used for placing glass ink sheets;

the feeding mechanism is arranged at a feeding station on the base and used for feeding the workpiece to the supporting frame;

the cleaner is arranged at a cleaning station on the base and is used for rapidly cleaning the upper surface of a workpiece on the support frame;

the magnetron sputtering device is arranged at a magnetron sputtering station on the base and is used for uniformly sputtering required substances on the upper surface of the cleaned workpiece to obtain a nano film glass ink sheet;

the blanking mechanism is arranged at a blanking station on the base and used for blanking the film-containing glass ink sheet on the support frame;

the sealing cover covers the upper surface of the base, the sealing cover and the base form a sealing space, and the conveying mechanism, the feeding mechanism, the cleaner, the magnetron sputtering device and the discharging mechanism are positioned in the sealing space;

the vacuumizing device is communicated with the sealed space through a pipeline and is used for vacuumizing the gas in the sealed space;

the feeding station, the cleaning station, the one or more magnetron sputtering stations and the discharging station are sequentially arranged along the annular track, the feeding mechanism feeds the glass ink sheet to the supporting frame, and each conveying block carries the glass ink sheet on the supporting frame on the conveying block, sequentially passes through the cleaning station, the magnetron sputtering station and the discharging station and circularly reciprocates.

2. The device for producing nano-film glass ink sheets for laser printing according to claim 1, wherein a feeding cavity is arranged on one side of the base, the feeding mechanism comprises a supporting plate which is arranged in the feeding cavity and can move up and down, the supporting plate is used for placing a glass substrate to be processed, and the supporting plate moves upwards for a preset height each time during feeding.

3. The device for producing nano-film glass ink sheets for laser printing according to claim 2, wherein the feeding mechanism further comprises four vertically arranged guide rods arranged around the supporting plate, the glass substrates can be just placed into a space surrounded by the guide rods when seen from top, and the upper ends of the four guide rods penetrate out from the upper end openings of the feeding cavity.

4. The apparatus for producing nano-film glass ink sheet for laser printing according to claim 1, wherein the feeding mechanism further comprises a conveying belt arranged right above the four guide bars, the conveying belt is arranged on the base through a mounting frame, the lower side portion of the conveying belt is horizontally arranged, the distance between the upper end of the guide bar close to the annular track and the lower surface of the lower side portion of the conveying belt among the four guide bars is greater than the thickness of one glass substrate and less than the thickness of two glass substrates, and the distance between the upper ends of the other three guide bars and the lower surface of the lower side portion of the conveying belt is less than the thickness of one glass substrate.

5. The device for producing nano-film glass ink sheets for laser printing according to claim 1, wherein the feeding mechanism further comprises a linear module and a clamping mechanism arranged at the output end of the linear module, the moving direction of the output end of the linear module is parallel to the conveying direction of the conveying belt, two ends of the linear module respectively extend to the position right above the annular track and the position right above the conveying belt, and the clamping mechanism can clamp the glass substrates output by the conveying belt.

6. The apparatus for producing nano-film glass ink sheet for laser printing according to claim 5, wherein the clamping mechanism comprises:

the vertical part is arranged at the output end of the linear module and can move up and down;

and the second clamping plate is horizontally arranged and is positioned right above the horizontal part, and the second clamping plate can move up and down relative to the first clamping plate so as to clamp or unclamp the glass substrate.

7. The apparatus for producing nano-film glass ink sheet for laser printing according to claim 1, wherein the supporting frame comprises:

the supporting seat is arranged on the conveying block;

four support arms, set up the up end at the supporting seat, the one end setting of every support arm is in the up end of supporting seat, and the other end is towards the direction of keeping away from the supporting seat extension and adjacent support arm mutually perpendicular, is provided with the bar groove of arranging along its extending direction on every support arm, is provided with a positioning bolt on every bar groove, positioning bolt can round trip movement in the extending direction in bar groove and can realize positioning bolt's fixed through screwing up the nut on the positioning bolt, and positioning bolt on four support arms can enclose into the space of placing of glass substrate.

8. The apparatus for producing nano-film glass ink sheet for laser printing according to claim 1, wherein the number of the magnetron sputterers is 1 or more, and the plurality of magnetron sputterers are sequentially arranged along the conveying direction of the conveying mechanism for sequentially sputtering different substances.

9. A method for producing nano-film glass ink sheet for laser printing, which adopts the device for producing nano-film glass ink sheet for laser printing according to any one of claims 1-8, and specifically comprises the following steps:

step S1: placing a glass substrate to be processed on a feeding mechanism, sealing by a sealing cover, and vacuumizing by a vacuumizing device;

step S2: the support frame moves to a feeding station, and the feeding mechanism moves the single glass substrate to the support frame;

step S3: the supporting frame moves to a cleaning station with the glass substrate, and the cleaner rapidly cleans the glass substrate after being fed;

step S4: the support frame moves to a magnetron sputtering station with the cleaned glass substrate, and one or more magnetron sputters uniformly sputter substances to the upper surface of the cleaned glass substrate in sequence to obtain the nano-film glass ink sheet;

step S5: the support frame moves to a blanking station with the obtained nano film glass ink sheet, and blanking is carried out on the nano film glass ink sheet obtained on the support frame;

the steps S2-S5 can be performed simultaneously, and the support frame can move among the feeding station, the cleaning station, one or more magnetron sputtering stations and the discharging station circularly and execute the steps S2-S5.