CN112060751B

CN112060751B - Nano-coating laser template and plate splicing method thereof

Info

Publication number: CN112060751B
Application number: CN202010968933.5A
Authority: CN
Inventors: 侯若洪
Original assignee: DONGGUAN SUNSHINE LASER & ELECTRONICS TECHNOLOGY Ltd
Current assignee: DONGGUAN SUNSHINE LASER & ELECTRONICS TECHNOLOGY Ltd
Priority date: 2020-09-15
Filing date: 2020-09-15
Publication date: 2021-10-26
Anticipated expiration: 2040-09-15
Also published as: CN112060751A

Abstract

The invention discloses a nano-coating laser template and a splicing method thereof, relates to the related field of laser templates, and aims to solve the problems that in the prior art, the template cannot be adapted to equipment with different specifications and no impurity slag residue is generated in gaps. The front end of master module is provided with the positioning strip, the master module is provided with a plurality ofly, the master module sets up to "concave" form down, the positioning strip is provided with two sets ofly, positioning strip every group is provided with two, two the positioning strip is symmetrical arrangement, the lower extreme of master module is provided with the connecting plate, the quantity of connecting plate sets up the twice to master module quantity, the front and back end of connecting plate all is provided with a connecting plate, the connecting plate passes through argon arc welding with the master module and is connected, be provided with first connecting hole on the connecting plate, the quantity of first connecting hole sets up to unanimously with the quantity of connecting plate, first connecting hole sets up to the round hole form.

Description

Nano-coating laser template and plate splicing method thereof

Technical Field

The invention relates to the related field of laser templates, in particular to a nano-coating laser template and a plate splicing method thereof.

Background

The laser cutting template is generally called as a laser template, the laser template is the most commonly used printing template in the SMT industry at present, and comprises a laser cutting steel template, an aluminum profile net frame for supporting the steel template and stainless steel wire gauze, the periphery of the gauze is tightened and is fixed on the net frame in a gluing way, and the edge of the steel template is fixed on a window in the gauze in a gluing way. In the prior art, the method for gluing and fixing the edge of the steel template and the window in the gauze comprises the following main steps: and (3) arranging a steel template in the middle of the back of the gauze qualified in the gauze tightening inspection, adopting a backing plate to enable the front of the steel template to be tightly jointed with the back of the gauze, sticking masking tapes on the gauze on two sides along each edge of the steel template, forming a rectangular or square primer layer coating area between the two side tapes, removing the masking tapes on two sides after coating the primer layer, and drying. After drying, continuously sticking masking tapes on two sides of the primer layer coating area, coating a surface adhesive layer on the surface of the primer layer, removing the masking tapes on two sides after coating the surface adhesive layer, and waiting for drying.

When the existing laser template is used, the existing laser template is mostly of a single plate-shaped structure, the phenomenon of equipment incompatibility is easily caused in the using process, but the separated jointed plate structure is very easy to cause residue of mixed slag in the gap of the jointed plate in the using process; therefore, the market urgently needs to develop a nano-coating laser template and a plate splicing method thereof to help people solve the existing problems.

Disclosure of Invention

The invention aims to provide a nano-coating laser template and a splicing method thereof, which are used for solving the problems that the template cannot be adapted to equipment with different specifications and the mixed slag residue cannot be generated in gaps in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: a nanometer coating laser template comprises a main template, wherein positioning strips are arranged at the front end of the main template, the main template is provided with a plurality of positioning strips, the main template is arranged into an inverted concave shape, two groups of positioning strips are arranged, each group of the positioning strips is provided with two positioning strips, the two positioning strips are symmetrically arranged, connecting plates are arranged at the lower end of the main template, the number of the connecting plates is twice that of the main template, the front end and the rear end of each connecting plate are respectively provided with one connecting plate, the connecting plates are connected with the main template through argon arc welding, first connecting holes are arranged on the connecting plates, the number of the first connecting holes is consistent with that of the connecting plates, the first connecting holes are arranged into a round hole shape, the depth of each first connecting hole is consistent with that of the connecting plates, and second connecting holes are arranged on the lower end faces of the positioning strips, the number of the second connecting holes is consistent with that of the connecting plates, the second connecting holes are in fit with the first connecting holes, the connecting plates are connected with the positioning strips through bolts and the second connecting holes, the positioning strips are internally provided with a plurality of extending strips, the extending strips are arranged into rectangular strips, the extending strips are in fit with the positioning strips, the extending strips are provided with limiting holes, the limiting holes are arranged into round holes, the limiting holes are provided with a plurality of limiting holes, the distance between two adjacent limiting holes is consistent, the depth of the limiting holes is consistent with the thickness of the extending strips, the limiting holes are provided with connecting bolts, the connecting plates and the extending strips are connected with the limiting holes through the connecting bolts and the first connecting holes, one side of the connecting bolts is provided with limiting studs, and the limiting studs are provided with a plurality of limiting studs, the limiting stud and the limiting hole are arranged to be attached, and the position adjusting strip and the extending strip are connected with the limiting hole through the limiting stud.

Preferably, the master template is provided with a plurality of hollow grooves, the distance between every two adjacent hollow grooves is set to be consistent, the depth of each hollow groove is set to be consistent with the thickness of the master template, one side of the master template is provided with a blocking strip, the blocking strips are provided with a plurality of blocking strips, the blocking strips are set to be T-shaped, the blocking strips and the master template are set to be attached, and the blocking strips and the master template are linearly arranged in a spaced mode.

Preferably, one side of positioning strip is provided with the mounting groove, the quantity of mounting groove sets up to unanimous with the quantity of positioning strip, the mounting groove sets up to the rectangle trough-like, one side of mounting groove is provided with the side shield, the side shield is provided with two, the side shield sets up to side "concave" form, be provided with installation slot on the side shield, installation slot is provided with four, installation slot sets up to the rectangle trough-like, installation slot's inside is provided with the mounting bar, the mounting bar is provided with four, mounting bar and side shield fixed connection, the mounting bar sets up to the laminating with the mounting groove, the side shield passes through the mounting groove with the positioning strip and is connected with the mounting bar.

Preferably, the lower extreme of installation slot is provided with the excess groove, the excess groove sets up to the rectangle trough-like, the width in excess groove sets up to unanimous with the width of side shield, one side in excess groove is provided with the mounting hole, the mounting hole is provided with two sets ofly, every group of mounting hole is provided with two, the mounting hole sets up to the round hole form, the degree of depth and the side shield thickness of mounting hole set up to unanimity.

Preferably, the lower extreme of side shield is provided with the separation blade, the separation blade sets up to rectangular plate, the separation blade is provided with two, the separation blade passes through argon arc welded connection with the side shield, one side of separation blade is provided with the bed plate, the bed plate sets up to rectangular plate, the bed plate passes through argon arc welded connection with the separation blade, the front end of bed plate is provided with the sediment case, the sediment case sets up to rectangular box form, the up end of sediment case and the up end of bed plate are located same horizontal plane, the sediment case passes through argon arc welded connection with the bed plate.

Preferably, one side of bed plate upper end is provided with electronic slide rail, electronic slide rail is provided with two, electronic slide rail and bed plate fixed connection, the inside of electronic slide rail is provided with electronic slider, electronic slider is provided with two, electronic slider sets up to the laminating with electronic slide rail, electronic slider sets up to electric connection with electronic slide rail, electronic slider's upper end is provided with the slagging-off board, the slagging-off board sets up to right angle trapezoidal form, remove slagging-off board and electronic slider fixed connection, the up end of bed plate is hugged closely to the lower terminal surface that removes the slagging-off board.

Preferably, the master template includes the nano coating, the nano coating coats in the up end of heat insulation layer, the lower extreme of nano coating is provided with the heat insulation layer, the lower extreme of heat insulation layer is provided with the adhesive linkage, the lower extreme of adhesive linkage is provided with the main part alloy-layer, the main part alloy-layer passes through the adhesive linkage with the heat insulation layer and is connected.

A plate splicing method for a nano-coating laser template comprises the following steps:

the method comprises the following steps: connecting the two side baffles with the equipment through the mounting holes in the side baffles, selecting a proper number of main templates according to the size of an object to be subjected to laser after the connection is confirmed, and assembling the main templates and the mounting strips on the side baffles through the mounting grooves in the positioning strips after the selection is finished;

step two: after the positioning strip is assembled, the limiting studs are rotated according to the distance between the two side baffles to adjust the relative position between the positioning strip and the extension strip, after the adjustment is confirmed, the first connecting holes in the main templates and the second connecting holes in the lower end face of the positioning strip are assembled through the studs, and redundant empty first connecting holes can be fixed with the limiting holes in the extension strip through the connecting bolts;

step three: after the assembly is completed, the barrier strips can be installed, and the barrier strips and the main template are ensured to be set to be attached, so that the plate splicing operation of the whole laser template can be completed.

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

1. according to the invention, through the arrangement of the main templates, the barrier strips, the positioning strips and the extension strips, when a user uses the nano-coating laser template, the device can be adapted to devices with different specifications by splicing the main templates, meanwhile, the positioning strips and the extension strips with adjustable relative positions are matched with the main templates for assembly, and through the arrangement of the barrier strips, the sealing treatment of gaps generated between the spliced plates of the two main templates is realized, so that the use cost of the whole laser template can be reduced to a certain extent;

2. according to the invention, through the arrangement of the side baffle and the allowance groove, when a user uses the nano-coating laser template, the user can adjust the positioning strip and the extension strip through the allowance groove arranged in the side baffle and the phenomenon that the connecting plate cannot correspond to the second connecting hole is generated, the main template can be moved to one part in the allowance groove, so that the first connecting holes on the connecting plate can correspond to the second connecting holes one by one again, and the installation efficiency of the whole nano-coating laser template during installation can be improved to a certain extent;

3. according to the invention, through the arrangement of the electric slide rail, the electric slide block, the slag removing plate and the slag storage box, a user can drive the slag removing plate to move on the base plate through the electric slide rail and the electric slide block which are electrically connected in the process of using the nano-coating laser template, so that the impurity slag falling from the hollow groove is removed, and then the impurity slag is conveyed into the slag storage box, and the use pressure of the user can be relieved to a certain extent.

Drawings

FIG. 1 is a schematic structural diagram of a nano-coating laser template and a plate splicing method thereof according to the present invention;

FIG. 2 is a schematic structural view of the base plate of the present invention;

FIG. 3 is a schematic bottom view of the positioning bar of the present invention;

FIG. 4 is a schematic structural diagram of a master template of the present invention;

FIG. 5 is a schematic bottom view of the master template of the present invention;

FIG. 6 is a schematic structural view of a side dam of the present invention;

fig. 7 is a schematic view of an internal structure of the master template of the present invention.

In the figure: 1. a master template; 2. engraving grooves; 3. blocking strips; 4. a connecting plate; 5. a first connection hole; 6. adjusting the position; 7. a second connection hole; 8. an extension bar; 9. a limiting hole; 10. a connecting bolt; 11. a limiting stud; 12. mounting grooves; 13. mounting a bar; 14. installing a clamping groove; 15. a side dam; 16. a residue tank; 17. mounting holes; 18. a base plate; 19. a baffle plate; 20. an electric slide rail; 21. a slag removal plate; 22. a slag storage box; 23. an electric slider; 24. a nano-coating; 25. a heat insulating layer; 26. an adhesive layer; 27. a main alloy layer.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1-7, an embodiment of the present invention is shown: a nano-coating laser template comprises a main template 1, wherein the front end of the main template 1 is provided with a plurality of positioning strips 6, the main template 1 is provided with a plurality of inverted concave main templates 1, two groups of positioning strips 6 are arranged, each group of the positioning strips 6 is provided with two positioning strips 6, the two positioning strips 6 are symmetrically arranged, the lower end of the main template 1 is provided with connecting plates 4, the number of the connecting plates 4 is twice that of the main template 1, the front end and the rear end of each connecting plate 4 are respectively provided with one connecting plate 4, the connecting plates 4 are connected with the main template 1 through argon arc welding, the connecting plates 4 are provided with first connecting holes 5, the number of the first connecting holes 5 is consistent with that of the connecting plates 4, the first connecting holes 5 are circular holes, the depth of the first connecting holes 5 is consistent with that of the connecting plates 4, the lower end faces of the positioning strips 6 are provided with second connecting holes 7, the number of the second connecting holes 7 is consistent with that of the connecting plates 4, the second connecting hole 7 is jointed with the first connecting hole 5, the connecting plate 4 is jointed with the position adjusting strip 6 through a bolt and the second connecting hole 7 is connected with the first connecting hole 5, the position adjusting strip 6 is internally provided with an extending strip 8, the extending strip 8 is arranged into a rectangular strip shape, the extending strip 8 is jointed with the position adjusting strip 6, the extending strip 8 is provided with a limiting hole 9, the limiting hole 9 is arranged into a round hole shape, the limiting holes 9 are provided with a plurality of holes, the distance between two adjacent limiting holes 9 is consistent, the depth of the limiting hole 9 is consistent with the thickness of the extending strip 8, the limiting hole 9 is provided with a connecting bolt 10, the connecting plate 4 is connected with the extending strip 8 through the connecting bolt 10, the first connecting hole 5 is connected with the limiting hole 9, one side of the connecting bolt 10 is provided with a limiting stud 11, the limiting studs 11 are provided with a plurality, the limiting studs 11 are jointed with the limiting holes 9, the position adjusting strip 6 is connected with the limiting holes 9 through the limiting studs 11 with the extending strips 8, the problem that the templates cannot be adapted to equipment with different specifications and the impurity slag residue cannot be generated in gaps is solved through arrangement of the structures.

Further, be provided with fretwork groove 2 on the master module 1, fretwork groove 2 is provided with a plurality ofly, distance between two adjacent fretwork grooves 2 sets up to unanimous, the degree of depth in fretwork groove 2 sets up to unanimous with the thickness of master module 1, one side of master module 1 is provided with blend stop 3, blend stop 3 is provided with a plurality ofly, blend stop 3 sets up to "T" form, blend stop 3 sets up to the laminating with master module 1, blend stop 3 is the linear arrangement of interval with master module 1, can be through the setting of blend stop 3, produced clearance when coming the master module 1 makeup seals.

Further, one side of positioning bar 6 is provided with mounting groove 12, the quantity of mounting groove 12 sets up to unanimous with the quantity of positioning bar 6, mounting groove 12 sets up to the rectangle trough-like, one side of mounting groove 12 is provided with side shield 15, side shield 15 is provided with two, side shield 15 sets up to side "concave" form, be provided with installation slot 14 on the side shield 15, installation slot 14 is provided with four, installation slot 14 sets up to the rectangle trough-like, installation slot 14's inside is provided with mounting bar 13, mounting bar 13 is provided with four, mounting bar 13 and side shield 15 fixed connection, mounting bar 13 sets up to the laminating with mounting groove 12, side shield 15 passes through mounting groove 12 with positioning bar 6 and is connected with mounting bar 13, can carry out fixed connection to positioning bar 6 through side shield 15.

Further, the lower extreme of installation draw-in groove 14 is provided with surplus groove 16, surplus groove 16 sets up to the rectangle trough-like, the width in surplus groove 16 sets up to unanimous with the width of side shield 15, one side in surplus groove 16 is provided with mounting hole 17, mounting hole 17 is provided with two sets ofly, mounting hole 17 is every group and is provided with two, mounting hole 17 sets up to the round hole form, the degree of depth of mounting hole 17 sets up to unanimous with the thickness of side shield 15, can adapt to positioning strip 6 and extension strip 8 through surplus groove 16 and carry out relative regulation.

Further, the lower extreme of side shield 15 is provided with separation blade 19, separation blade 19 sets up to rectangular plate, separation blade 19 is provided with two, separation blade 19 passes through argon arc welded connection with side shield 15, one side of separation blade 19 is provided with bed plate 18, bed plate 18 sets up to rectangular plate, bed plate 18 passes through argon arc welded connection with separation blade 19, the front end of bed plate 18 is provided with deposit box 22, deposit box 22 sets up to rectangular box, the up end of deposit box 22 is located same horizontal plane with the up end of bed plate 18, deposit box 22 passes through argon arc welded connection with bed plate 18, can store the miscellaneous sediment that produces because of laser operation through deposit box 22 and collect.

Further, one side of bed plate 18 upper end is provided with electronic slide rail 20, electronic slide rail 20 is provided with two, electronic slide rail 20 and bed plate 18 fixed connection, electronic slide rail 20's inside is provided with electronic slider 23, electronic slider 23 is provided with two, electronic slider 23 sets up to the laminating with electronic slide rail 20, electronic slider 23 sets up to electric connection with electronic slide rail 20, electronic slider 23's upper end is provided with except that slag plate 21, it sets up to right angle trapezoidal form to remove slag plate 21, remove slag plate 21 and electronic slider 23 fixed connection, the up end of bed plate 18 is hugged closely to the lower terminal surface that removes slag plate 21, can remove slag plate 21 with electronic slide rail 20 drive through electronic slider 23, thereby realize the cleaing away to miscellaneous sediment.

Further, the main template 1 includes the nano coating 24, the nano coating 24 is coated on the upper end surface of the heat insulating layer 25, the heat insulating layer 25 is disposed at the lower end of the nano coating 24, the adhesive layer 26 is disposed at the lower end of the heat insulating layer 25, the main alloy layer 27 is disposed at the lower end of the adhesive layer 26, the main alloy layer 27 is connected to the heat insulating layer 25 through the adhesive layer 26, and the nano coating 24 and the heat insulating layer 25 can be disposed to improve the physical properties of the whole main template 1.

the method comprises the following steps: the connection between the two side baffles 15 and the equipment is completed through the mounting holes 17 on the side baffles 15, after the connection is confirmed, a proper number of main templates 1 are selected according to the size of an object to be subjected to laser, and after the selection is completed, the main templates are assembled through the mounting grooves 12 on the positioning bars 6 and the mounting bars 13 on the side baffles 15;

step two: after the positioning bar 6 is assembled, the limiting studs 11 are rotated according to the distance between the two side baffles 15 to adjust the relative positions of the positioning bar 6 and the extension bar 8, after the adjustment is confirmed, the first connecting holes 5 on the main templates 1 and the second connecting holes 7 on the lower end face of the positioning bar 6 are assembled through the studs, and the redundant empty first connecting holes 5 can be fixed with the limiting holes 9 on the extension bar 8 through the connecting bolts 10;

step three: after the assembly is completed, the barrier strips 3 can be installed, and the barrier strips 3 and the main template 1 are ensured to be attached, so that the splicing operation of the whole laser template can be completed.

The working principle is as follows: when the nano coating laser template is used, the whole nano coating laser template is firstly checked, a user can start to use the nano coating laser template after confirming that the check is correct, the user can finish the connection between the two side baffles 15 and equipment through the mounting holes 17 on the side baffles 15, after confirming that the connection is finished, the main templates 1 with proper quantity are selected according to the size of an object to be laser, after the selection is finished, the main templates are assembled with the mounting strips 13 on the side baffles 15 through the mounting grooves 12 on the positioning strips 6, after the positioning strips 6 are assembled, the limiting studs 11 are rotated according to the distance between the two side baffles 15 to adjust the relative positions between the positioning strips 6 and the extension strips 8, after the adjustment is confirmed, the first connecting holes 5 on the main templates 1 are respectively assembled with the second connecting holes 7 on the lower end faces of the positioning strips 6 through the studs, and redundant empty first connecting holes 5 can be fixed with the limiting holes 9 on the extension strips 8 through the connecting bolts 10, when the assembly is completed, the barrier strips 3 can be installed, and the barrier strips 3 and the main template 1 are ensured to be arranged in a joint manner, so that the plate splicing operation of the whole laser template can be completed, and in the process of using the nano-coating laser template, when the phenomenon that the connecting plates 4 cannot correspond to the second connecting holes 7 due to the fact that the positioning strips 6 and the extension strips 8 are adjusted through the allowance grooves 16 arranged in the side baffles 15, the main template 1 can be moved to a part in the allowance grooves 16, so that the first connecting holes 5 on the connecting plates 4 can correspond to the second connecting holes 7 one by one, the installation efficiency of the whole nano-coating laser template during installation can be improved to a certain degree, and meanwhile, the slag removing plates 21 can be driven to move on the base plate 18 through the electric slide rails 20 and the electric slide blocks 23 which are electrically connected, so that the miscellaneous slag falling from the hollow grooves 2 can be removed, thereby realizing that the miscellaneous slag is sent into the slag storage box 22, and relieving the use pressure of users to a certain extent.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. A nano-coating laser template comprises a master template (1) and is characterized in that: the front end of the main template (1) is provided with positioning strips (6), the main template (1) is provided with a plurality of positioning strips, the main template (1) is arranged in an inverted concave shape, the positioning strips (6) are provided with two groups, each group of the positioning strips (6) is provided with two positioning strips (6), the two positioning strips (6) are symmetrically arranged, the lower end of the main template (1) is provided with connecting plates (4), the number of the connecting plates (4) is twice that of the main template (1), the front end and the rear end of each connecting plate (4) are provided with one connecting plate (4), the connecting plates (4) are connected with the main template (1) through argon arc welding, the connecting plates (4) are provided with first connecting holes (5), the number of the first connecting holes (5) is consistent with that of the connecting plates (4), the first connecting holes (5) are arranged in a round hole shape, the depth of the first connecting holes (5) is consistent with the thickness of the connecting plates (4), the lower end face of the position adjusting strip (6) is provided with second connecting holes (7), the number of the second connecting holes (7) is consistent with the number of the connecting plates (4), the second connecting holes (7) are laminated with the first connecting holes (5), the connecting plates (4) are connected with the position adjusting strip (6) through bolts and the second connecting holes (7) with the first connecting holes (5), the inside of the position adjusting strip (6) is provided with extension strips (8), the extension strips (8) are arranged into rectangular strips, the extension strips (8) are laminated with the position adjusting strip (6), the extension strips (8) are provided with limiting holes (9), the limiting holes (9) are arranged into round holes, the limiting holes (9) are arranged in a plurality, and the distance between two adjacent limiting holes (9) is consistent, the depth of the limiting hole (9) is consistent with the thickness of the extending strip (8), a connecting bolt (10) is arranged on the limiting hole (9), the connecting plate (4) and the extending strip (8) are connected with the limiting hole (9) through the connecting bolt (10) and the first connecting hole (5), a plurality of limiting studs (11) are arranged on one side of the connecting bolt (10), the limiting studs (11) are arranged to be attached to the limiting hole (9), the position adjusting strip (6) and the extending strip (8) are connected with the limiting hole (9) through the limiting studs (11), a mounting groove (12) is formed in one side of the position adjusting strip (6), the number of the mounting grooves (12) is consistent with the number of the position adjusting strips (6), the mounting groove (12) is in a rectangular groove shape, and a side baffle (15) is arranged on one side of the mounting groove (12), the side baffle (15) is provided with two side baffles, the side baffles (15) are arranged in a side concave shape, the side baffles (15) are provided with four installation clamping grooves (14), the installation clamping grooves (14) are arranged in a rectangular groove shape, an installation strip (13) is arranged in the installation clamping groove (14), the installation strip (13) is arranged in four, the installation strip (13) is fixedly connected with the side baffles (15), the installation strip (13) is attached to the installation groove (12), the side baffles (15) and the positioning strip (6) are connected with the installation strip (13) through installation grooves (12), the lower end of the installation clamping groove (14) is provided with a residual groove (16), the residual groove (16) is arranged in a rectangular groove shape, the width of the residual groove (16) is consistent with the width of the side baffles (15), and one side of the residual groove (16) is provided with an installation hole (17), the mounting hole (17) is provided with two sets ofly, every group of mounting hole (17) is provided with two, mounting hole (17) sets up to the round hole form, the degree of depth of mounting hole (17) sets up to unanimous with the thickness of side shield (15), the lower extreme of side shield (15) is provided with separation blade (19), separation blade (19) set up to rectangular plate form, separation blade (19) are provided with two, separation blade (19) and side shield (15) are connected through argon arc welding, one side of separation blade (19) is provided with bed plate (18), bed plate (18) set up to rectangular plate form, bed plate (18) and separation blade (19) are connected through argon arc welding, the front end of bed plate (18) is provided with deposit case (22), deposit case (22) set up to rectangular box form, the up end of deposit case (22) is located same horizontal plane with the up end of bed plate (18), deposit sediment case (22) and bed plate (18) and be connected through argon arc welding, one side of bed plate (18) upper end is provided with electronic slide rail (20), electronic slide rail (20) are provided with two, electronic slide rail (20) and bed plate (18) fixed connection, the inside of electronic slide rail (20) is provided with electronic slider (23), electronic slider (23) are provided with two, electronic slider (23) set up to the laminating with electronic slide rail (20), electronic slider (23) set up to electric connection with electronic slide rail (20), the upper end of electronic slider (23) is provided with except that slaggy (21), it sets up to the right angle trapezoidal form to remove slaggy (21), remove slaggy (21) and electronic slider (23) fixed connection, the up end of bed plate (18) is hugged closely to the lower terminal surface that removes slaggy (21).

2. The nanolayered coated laser template of claim 1, wherein: be provided with fretwork groove (2) on master template (1), fretwork groove (2) are provided with a plurality ofly, and adjacent two distance between fretwork groove (2) sets up to unanimous, the degree of depth of fretwork groove (2) sets up to unanimous with the thickness of master template (1), one side of master template (1) is provided with blend stop (3), blend stop (3) are provided with a plurality ofly, blend stop (3) set up to "T" form, blend stop (3) set up to the laminating with master template (1), blend stop (3) are interval mode linear arrangement with master template (1).

3. The nanolayered coated laser template of claim 1, wherein: the master template (1) comprises a nano coating (24), the nano coating (24) is coated on the upper end face of a heat insulating layer (25), the lower end of the nano coating (24) is provided with the heat insulating layer (25), the lower end of the heat insulating layer (25) is provided with an adhesive layer (26), the lower end of the adhesive layer (26) is provided with a main body alloy layer (27), and the main body alloy layer (27) is connected with the heat insulating layer (25) through the adhesive layer (26).

4. A plate splicing method of a nano-coating laser template is realized on the basis of any one nano-coating laser template in claims 1-3, and is characterized by comprising the following steps:

the method comprises the following steps: the connection between the two side baffles (15) and the equipment is completed through the mounting holes (17) on the side baffles (15), after the connection is confirmed to be completed, a proper number of main templates (1) are selected according to the size of an object to be subjected to laser, and after the selection is completed, the main templates are assembled through the mounting grooves (12) on the positioning bars (6) and the mounting bars (13) on the side baffles (15);

step two: after the positioning strips (6) are assembled, the limiting studs (11) are rotated according to the distance between the two side baffles (15) to adjust the relative positions between the positioning strips (6) and the extension strips (8), after the adjustment is confirmed, the first connecting holes (5) in the main templates (1) and the second connecting holes (7) in the lower end faces of the positioning strips (6) are assembled through the studs, and the redundant empty first connecting holes (5) can be fixed with the limiting holes (9) in the extension strips (8) through the connecting bolts (10);

step three: after the assembly is completed, the barrier strips (3) can be installed, and the barrier strips (3) and the main template (1) are guaranteed to be attached, so that the splicing operation of the whole laser template can be completed.