CN109927394B

CN109927394B - Blue light net making machine

Info

Publication number: CN109927394B
Application number: CN201711356381.7A
Authority: CN
Inventors: 陈路
Original assignee: Shaoxing Haochun Textile Technology Co ltd
Current assignee: Shaoxing Haochun Textile Technology Co ltd
Priority date: 2017-12-16
Filing date: 2017-12-16
Publication date: 2021-07-20
Anticipated expiration: 2037-12-16
Also published as: CN109927394A

Abstract

The invention discloses a blue light screen making machine, which relates to the technical field of printing screen making equipment and comprises a workbench, support tables arranged on two sides of the workbench in a sliding manner, cross beams with two ends connected to the support tables respectively, a machine head connected to the cross beams in a sliding manner, and a transmission device arranged in the support tables and used for driving the machine head to move, wherein 64 paths of lasers, a heat dissipation device attached to the 64 paths of lasers and a driving device which is arranged on one side of the 64 paths of lasers and electrically connected with the 64 paths of lasers and used for driving the 64 paths of lasers to work are arranged in the support tables. The machine head comprises an optical fiber close-packed module and an optical lens, wherein the optical fiber close-packed module comprises 64 optical fibers, the 64 optical fibers are divided into two rows with equal quantity, and the two rows of optical fibers are arranged in a staggered manner and connected with 64 paths of lasers; the optical lens is arranged on the other side of the optical fiber close-packed module; the optical fiber close-packed module increases the flux of laser by arranging 2 rows of 32 optical fibers in parallel, thereby improving the efficiency of laser net making.

Description

Blue light net making machine

Technical Field

The invention relates to the technical field of printing screen making equipment, in particular to a blue light screen making machine.

Background

A blue light screen making machine is a flat screen printing screen making device, mainly using a semiconductor laser to expose a flat screen printing screen coated with glue and cured at low temperature under the control of a computer, so that the glue on the part irradiated by light is instantly cured to form a pattern, and the part not irradiated by light can be washed away by clear water, thereby obtaining the flat screen printing screen.

The existing blue light net making machine generally comprises a workbench for placing a net plate, a beam is horizontally arranged above the workbench, two ends of the beam are respectively fixed with a support table connected to two sides of the workbench in a sliding manner, a machine head used for emitting light is connected to the beam in a sliding manner, and a transmission device used for driving the machine head to move is arranged in the support table on one side. The transmission device generally adopts a motor and a synchronous belt, the motor drives the synchronous belt to work when working, and finally the synchronous belt drives the machine head to move along the cross beam. After the operator places the glued screen plate on the workbench, the transmission device is utilized to drive the machine head to move along the cross beam, so that light emitted from the machine head can directly irradiate on the screen plate for exposure.

The existing machine head generally comprises an optical fiber close-packed module, an optical lens, a multi-path laser and a heat dissipation device, wherein one end of the optical fiber close-packed module is connected with the multi-path laser, and the other end of the optical fiber close-packed module irradiates a screen plate after being condensed by the optical lens. In the optical fiber close-packed module, the optical fibers are usually closely packed in a row, and due to the limitation of the length direction, the optical loss of the optical fiber close to the outer side of the optical lens is larger and the optical loss is not favorable for the effective utilization of the laser once the optical fibers are arranged more, the optical path passing through the optical lens is longer. Therefore, the prior blue-ray net making machine generally adopts 32-path or 48-path laser, and the efficiency of laser net making is not high.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a blue-light net making machine, wherein two rows of 32 optical fibers are arranged on an optical fiber close-packed module, so that the flux of laser is improved, and the net making efficiency of the laser is improved.

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

a blue light net making machine comprises a workbench, support tables arranged on two sides of the workbench in a sliding mode, a cross beam with two ends connected to the support tables respectively, a machine head connected to the cross beam in a sliding mode, and a transmission device arranged in the support tables and used for driving the machine head to move, wherein 64 paths of lasers, a heat dissipation device attached to the 64 paths of lasers in a clinging mode, and a driving device located on one side of the 64 paths of lasers and electrically connected with the 64 paths of lasers and used for driving the 64 paths of lasers to work are arranged in the support tables;

the handpiece comprises an optical fiber close-packed module and an optical lens, the optical fiber close-packed module comprises 64 optical fibers, the 64 optical fibers are divided into two rows with equal quantity, and the two rows of optical fibers are arranged in a staggered manner and connected with the 64-path laser; the optical lens is arranged on the other side of the optical fiber close-packed module.

By adopting the technical scheme, the 64 optical fibers are arranged on the optical fiber close-packed module in a parallel mode, so that the number of the optical fibers is increased, the loss of an optical path is not easy to cause, and the efficiency of laser net making is improved; in addition, the 64-channel laser and the heat dissipation device are arranged on the support table, so that the load on the machine head is directly reduced, when the transmission device drives the machine head to move, the acting force of a synchronous belt in the transmission device on the machine head can be directly reduced due to the reduction of the load, the probability that the synchronous belt is damaged is reduced, the integral use quality of the equipment is improved, and the working efficiency is improved; the driving device is arranged on one side, close to the 64 paths of lasers, of the supporting platform, and the stability of current transmitted to the 64 paths of lasers by the driving device can be improved, so that the light emitting stability of the 64 paths of lasers is improved, and the exposure uniformity of the screen plate is improved.

Further, the 64-path laser is equally divided into two 32-path lasers with the same number, and each 32-path laser is electrically connected with the driving device.

Through adopting above-mentioned technical scheme, equally divide into two 32 way lasers with 64 way lasers, can shorten 64 way lasers length in the brace table to reduce the occupation space of brace table.

Furthermore, the heat dissipation device is fixedly connected between each 32-path laser and the support platform.

By adopting the technical scheme, each 32-path laser is provided with the corresponding heat dissipation device, so that the heat dissipation of the corresponding 32-path laser can be realized through the heat dissipation devices, and the working stability of the 32-path laser is improved; in addition, the heat dissipation device is separately arranged, so that the installation position of the 32-path laser is flexible.

Further, the handpiece further includes:

the sliding plate is connected with the cross beam in a sliding manner;

the positioning plate is fixedly connected to one side of the sliding plate, which is far away from the cross beam;

the distance adjusting plate is connected with the positioning plate in a sliding manner along the direction close to/far away from the workbench;

the positioning device is connected with the positioning plate and the distance adjusting plate and used for limiting the positions of the distance adjusting plate and the positioning plate;

the optical fiber close-packed module and the optical lens are fixedly arranged on the distance adjusting plate.

Through adopting above-mentioned technical scheme, positioner can inject the distance between roll adjustment board and the locating plate to reach the purpose of adjusting the object distance, make the laser of penetrating through optical lens can focus on the otter board, further improve the efficiency of laser system net.

Further, positioner is including first hangers and second hangers in roll adjustment board and locating plate respectively fixed connection, first hangers and second hangers are located same vertical line, just first hangers are located second hangers top, set up threaded hole on the first hangers, an adjusting bolt with the back butt in is connected to the screw hole the second hangers.

Through adopting above-mentioned technical scheme, rotate adjusting bolt and can change the distance between first hangers and the second hangers to the distance between adjustable roll adjustment board and the otter board finally reaches the purpose of roll adjustment.

Furthermore, a rotating device which is rotationally connected with the optical fiber close-packed module is further arranged on the distance adjusting plate.

Through adopting above-mentioned technical scheme, the angle of the adjustable optic fibre close packing module of rotating device for laser through optical lens can accord with the operating mode more.

Furthermore, the rotating device comprises a base arranged on the distance adjusting plate and a rotary table rotatably connected with the base, the optical fiber dense-arrangement module is fixedly connected to the rotary table, and the base is further provided with a driving device for driving the rotary table to rotate.

Through adopting above-mentioned technical scheme, drive arrangement can drive and take place relative rotation between revolving stage and the base to drive the optical fiber close-packed module rotation that sets up on the revolving stage, reach the purpose of adjusting optical fiber close-packed module light-emitting angle.

Furthermore, a clamping groove is formed in the middle of the rotary table, a clamping block clamped with the clamping groove is arranged at the joint of the optical fiber close packing module and the rotary table, a clamping piece is arranged at one end, far away from the rotary table, of the optical fiber close packing module, and a fixing piece clamped with the clamping piece is detachably arranged on the distance adjusting plate.

Through adopting above-mentioned technical scheme, in the draw-in groove of fixture block joint on the revolving stage was utilized to optical fiber close packing module one end, the other end passed through joint spare and mounting fixed to fix optical fiber close packing module on the roll adjustment board.

Furthermore, the driving device comprises a worm wheel which is arranged in the base and fixedly connected with the rotary table, and a worm which is rotatably arranged on the base and meshed with the worm wheel.

By adopting the technical scheme, the worm can be rotated to drive the turbine to rotate, so that the rotary table is driven to rotate, and the purpose of rotating the angle of the optical fiber close-packed module is achieved.

Further, a ball is arranged on the periphery of the turntable.

Through adopting above-mentioned technical scheme, can reduce the friction between revolving stage and the base for the revolving stage rotates comparatively easily.

Compared with the prior art, the invention has the advantages that:

1. the optical fiber close-packed module increases the flux of laser by arranging 2 rows of 32 optical fibers in parallel, thereby improving the efficiency of laser net making;

2. the positioning device can limit the distance between the distance adjusting plate and the positioning plate, so that the purpose of adjusting the object distance is achieved, the laser emitted by the optical lens can be focused on the screen plate, and the laser screen manufacturing efficiency is further improved;

3. the rotating device can adjust the angle of the optical fiber close packing module, so that the laser passing through the optical lens can better meet the working condition;

4. by arranging the 64-path laser and the heat dissipation device on the support table, the weight of the machine head is reduced, so that the load of a synchronous belt in a transmission device can be reduced, the probability of damage of the synchronous belt is reduced, and the working efficiency of a blue-ray net making machine is improved;

5. the driving device is arranged on one side of the 64-path laser, so that the stability of the current input into the 64-path laser by the driving device is improved.

Drawings

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

FIG. 2 is an enlarged view of portion A of FIG. 1;

FIG. 3 is a simplified schematic of the transmission;

FIG. 4 is a perspective view of the handpiece of FIG. 1;

FIG. 5 is an exploded view of FIG. 4;

FIG. 6 is a schematic cross-sectional view of a fiber-optic close-packed module.

Reference numerals: 1. a work table; 2. a support table; 21. a 64-way laser; 22. a heat sink; 23. a drive device; 24. a transmission device; 241. a motor; 242. a driving wheel; 243. a synchronous belt; 244. a driven wheel; 25. a support pillar; 3. a cross beam; 4. a handpiece structure; 41. a slide plate; 42. positioning a plate; 421. a slider; 43. a distance adjusting plate; 431. a chute; 44. a positioning device; 441. a first suspension loop; 442. a second suspension loop; 443. a threaded hole; 444. adjusting the bolt; 445. a groove; 45. the optical fiber close-packed module; 46. an optical lens; 47. a rotating device; 471. a base; 472. a turntable; 473. a card slot; 474. a clamping block; 475. a clamping piece; 476. a fixing member; 481. a turbine; 482. a worm.

Detailed Description

The invention is described in detail below with reference to the figures and examples.

The utility model provides a novel blue light net making machine, refers to figure 1, including the workstation 1 that is used for placing the otter board, 1 both sides of workstation slide and are provided with a supporting

bench

2, and 3 both ends of a crossbeam fixed connection respectively are parallel with the mesa of workstation 1 on the supporting bench 2 of both sides. The crossbeam 3 slides on and is connected with the aircraft nose that is used for transmitting light, and during operation, places the otter board on workstation 1, exposes to the glue on the otter board through the light of aircraft nose department transmission, finally obtains the otter board of setting for the pattern.

Referring to fig. 2, a support column 25 is provided in the support table 2, and the cross beam 3 is fixedly connected to the support column 25 by bolts. With reference to fig. 2 and 3, a transmission device 24 for driving the machine head to move is arranged in the support table 2, the transmission device 24 includes a motor 241 fixedly connected to the support table 2, a driving wheel 242 coaxially connected to a rotating shaft of the motor 241, a driven wheel 244 rotatably connected to the support table 2 on the other side, and a synchronous belt 243 for driving and connecting the driving wheel 242 and the driven wheel 244, a sliding plate 41 is fixed on the synchronous belt 243, the machine head is fixedly connected to the sliding plate 41, and the sliding plate 41 is slidably connected to the beam 3; when the motor 241 is operated, the timing belt 243 is driven to rotate, so as to drive the head on the sliding plate 41 to move.

The support table 2 is internally provided with 64 paths of lasers 21 and a heat dissipation device 22 closely attached to the 64 paths of lasers 21, in the embodiment, the 64 paths of lasers 21 adopt 64 paths of lasers 21, the 64 paths of lasers 21 are equally divided into two 32 paths of lasers, the heat dissipation device 22 is fixedly connected between each 32 paths of lasers and the support table 2 through bolts, and the heat dissipation device 22 can adopt aluminum heat dissipation fins. A driving device 23 electrically connected to the 64-channel laser 21 and used for driving the 64-channel laser 21 to operate is further provided on the side of the 64-channel laser 21 in the support table 2. The driving device 23 is arranged on one side, close to the 64 paths of lasers 21, in the supporting platform 2, the stability of current transmitted to the 64 paths of lasers 21 by the driving device 23 can be improved, so that the light emitting stability of the 64 paths of lasers 21 is improved, and the uniformity of screen exposure is improved.

Referring to fig. 4 and 5, the machine head includes a sliding plate 41 connected with the cross beam 3 in a sliding manner, a positioning plate 42 is fixed on one side of the sliding plate 41 away from the cross beam 3 by a bolt, a sliding block 421 is integrally arranged on one side of the positioning plate 42 away from the sliding plate 41, and a distance adjusting plate 43 provided with a sliding groove 431 is connected with the positioning plate 42 in a sliding manner, wherein the sliding block 421 is matched with the sliding groove 431 in a sliding manner and can move along the direction close to/away from the workbench 1, so that the distance between the distance adjusting plate 43 and the workbench 1 is changed. The positioning plate 42 is further provided with a positioning device 44 for connecting the positioning plate 42 and the distance adjusting plate 43 and limiting the positions of the distance adjusting plate 43 and the positioning plate 42, so that the distance adjusting plate 43 can be fixed.

The positioning device 44 includes a first hanging lug 441 and a second hanging lug 442 fixedly connected to the distance adjusting plate 43 and the positioning plate 42, respectively, the first hanging lug 441 and the second hanging lug 442 are located on the same vertical line, and the first hanging lug 441 is located above the second hanging lug 442. The first hanging lug 441 is provided with a threaded hole 443, and an adjusting bolt 444 is connected with the threaded hole 443 and abuts against the second hanging lug 442. The end of the adjusting bolt 444, which is in contact with the second hanging lug 442, is spherically arranged, and a groove 445 matched with one end of the adjusting bolt 444 is arranged on the second hanging lug 442. The distance between the first hanging lug 441 and the second hanging lug 442 can be adjusted by rotating the adjusting bolt 444, so that the purpose of adjusting the distance between the distance adjusting plate 43 and the workbench 1 is achieved; then under the effect of the self gravity of the distance adjusting plate 43, the adjusting bolt 444 can be clamped with the groove 445, and the distance adjusting plate 43 is prevented from shaking when the sliding plate 41 moves along the cross beam 3.

The distance adjusting plate 43 is further provided with a rotating device 47 which is rotatably connected with the optical fiber close-packed module 45. The distance adjusting plate 43 is fixed with a base 471 through bolts, the upper end of the base 471 is rotatably connected with a rotating platform 472, and balls are arranged on the peripheral side of the rotating platform 472, so that friction between the rotating platform 472 and the base 471 can be reduced. A clamping groove 473 is formed in the middle of the rotary table 472, and the optical fiber close-packed module 45 provided with the clamping block 474 is clamped with the clamping groove 473, so that the optical fiber close-packed module 45 is fixed to the rotary table 472. In order to improve the stability of the connection between the optical fiber close-packed module 45 and the rotary table 472, a clamping piece 475 is arranged at one end of the optical fiber close-packed module 45, which is far away from the rotary table 472, and a fixing piece 476 clamped with the clamping piece 475 is fixed on the distance adjusting plate 43 through a bolt. It should be noted that the latch 475 can rotate about the fixing member 476.

The base 471 is internally provided with a driving device 23 for driving the rotating table 472 to rotate, so as to achieve the purpose of adjusting the angle of the optical fiber close-packed module 45. The driving device 23 includes a worm wheel 481 disposed in the base 471 and fixedly connected to the turn table 472, and a worm 482 rotatably disposed on the base 471 and engaged with the worm wheel 481, wherein the worm wheel 482 rotates the worm wheel 481, so that the optical fiber packing module 45 disposed on the turn table 472 rotates.

An optical lens 46 is disposed below the base 471, and the laser light transmitted from the optical fiber close-packed module 45 is converged at the optical lens 46 and irradiated onto the worktable 1.

In this embodiment, referring to fig. 5, one end of the optical fiber close-packed module 45 is provided with 64 optical fibers, which are electrically connected to 64 laser devices 21, and the 64 optical fibers are divided into two rows with equal number, and the two rows of optical fibers are arranged in a staggered manner, so that the number of the optical fibers is increased, the flux of laser is increased, and the net making efficiency of the net making machine can be improved.

The working principle of the invention is as follows:

the 64-path laser 21 and the heat dissipation device 22 are arranged in the support table 2, so that the load at the machine head is reduced, the probability that the synchronous belt 243 for driving the machine head to move is damaged is reduced, and the working efficiency of the screen making machine is improved; meanwhile, the driving device 23 is arranged at one side of the 64-path laser 21, so that the stability of the current input into the 64-path laser 21 is improved, and the uniformity of screen exposure is improved.

When the net is manufactured, firstly, electrifying is carried out, so that laser can irradiate the workbench 1 through the optical lens 46; then, the adjusting bolt 444 is turned to adjust the distance between the optical lens 46 and the table 1; then, the worm 482 is rotated to adjust the angle of the optical fiber close-packed module 45, so that the laser emitted from the optical lens 46 can be more suitable for the working condition to irradiate the screen plate for screen making.

The optical fiber close-packed module 45 adopts 64 optical fibers, so that the laser flux is increased, and the net making efficiency of the net making machine can be improved.

The above description is only a preferred embodiment of the present invention, and the protection scope of the present invention is not limited to the above embodiments, and all technical solutions belonging to the idea of the present invention belong to the protection scope of the present invention. It should be noted that modifications and embellishments within the scope of the invention may occur to those skilled in the art without departing from the principle of the invention, and are considered to be within the scope of the invention.

Claims

1. A blue light net making machine comprises a workbench (1), support tables (2) arranged on two sides of the workbench (1) in a sliding manner, a cross beam (3) with two ends respectively connected to the support tables (2), a machine head connected to the cross beam (3) in a sliding manner, and a transmission device (24) arranged in the support tables (2) and used for driving the machine head to move, and is characterized in that 64 paths of lasers (21), a heat dissipation device (22) closely attached to the 64 paths of lasers (21), and a driving device (23) which is arranged on one side of the 64 paths of lasers (21) and electrically connected with the 64 paths of lasers (21) and used for driving the 64 paths of lasers (21) to work are arranged in the support tables (2);

the handpiece comprises an optical fiber close-packed module (45) and an optical lens (46), the optical fiber close-packed module (45) comprises 64 optical fibers, wherein the 64 optical fibers are divided into two rows with equal quantity, and the two rows of optical fibers are arranged in a staggered manner and connected with the 64-path laser (21); the optical lens (46) is arranged on the other side of the optical fiber close-packed module (45);

the handpiece further includes:

the sliding plate (41) is connected with the cross beam (3) in a sliding manner;

the positioning plate (42) is fixedly connected to one side, far away from the cross beam (3), of the sliding plate (41);

the distance adjusting plate (43) is connected with the positioning plate (42) in a sliding manner through a sliding block (421) and a sliding groove (431) along the direction of approaching to/departing from the workbench (1);

a positioning device (44) connecting the positioning plate (42) and the distance adjusting plate (43) for limiting the position of the distance adjusting plate (43) and the positioning plate (42);

the optical fiber close-packed module (45) and the optical lens (46) are fixedly arranged on the distance adjusting plate (43), wherein the positioning device (44) comprises a first lug (441) and a second lug (442) which are respectively and fixedly connected to the distance adjusting plate (43) and the positioning plate (42), the first lug (441) and the second lug (442) are positioned on the same vertical line, the first lug (441) is positioned above the second lug (442), a threaded hole (443) is formed in the first lug (441), and an adjusting bolt (444) is connected with the threaded hole (443) and then abuts against the second lug (442).

2. The blue-ray net making machine according to claim 1, wherein the 64-path laser (21) is divided into two 32-path lasers with the same number, and each of the 32-path lasers is electrically connected with the driving device (23).

3. The blue-ray screen making machine according to claim 2, wherein the heat dissipation device (22) is fixedly connected between each 32-way laser and the support table (2).

4. The blue-ray net making machine according to claim 1, wherein the distance adjusting plate (43) is further provided with a rotating device (47) rotatably connected with the optical fiber close-packed module (45).

5. The blue-ray screen making machine according to claim 4, wherein the rotating device (47) comprises a base (471) arranged on the distance adjusting plate (43) and a rotating platform (472) rotatably connected with the base (471), the optical fiber close-packed module (45) is fixedly connected to the rotating platform (472), and a driving device (23) for driving the rotating platform (472) to rotate is further arranged on the base (471).

6. The blue-ray net making machine according to claim 5, wherein a clamping groove (473) is arranged in the middle of the rotary table (472), a clamping block (474) clamped with the clamping groove (473) is arranged at the joint of the optical fiber close-packed module (45) and the rotary table (472), a clamping piece (475) is arranged at one end, away from the rotary table (472), of the optical fiber close-packed module (45), and a fixing piece (476) clamped with the clamping piece (475) is detachably arranged on the distance adjusting plate (43).

7. The blue-ray screen making machine according to claim 6, wherein the driving device (23) comprises a turbine (481) arranged in the base (471) and fixedly connected with the rotary table (472), and a worm (482) rotatably arranged on the base (471) and engaged with the turbine (481).

8. Blue lapper according to claim 7, characterized in that the peripheral side of the turntable (472) is provided with balls.