CN211162432U - High-speed ultraviolet laser cutting FPC device of two mirrors that vibrate - Google Patents

Abstract

The utility model relates to the technical field of FPC equipment, the utility model discloses a double-vibrating-mirror high-speed ultraviolet laser FPC cutting device, which comprises a bracket (1), a feeding mechanism (2), a honeycomb panel platform (3), a smoking mechanism (4), a visual positioner (5), a laser cutting mechanism (6) and a discharging mechanism (7); the beneficial effects of the utility model reside in that: this design uses two lasers, realizes that two mirrors independently process FPC product function that shake, and each lens during operation that shakes does not influence each other, greatly promotes work efficiency, has cancelled the lens subassembly that shakes of traditional model by XY motion axis driven mechanical structure, can effectively reduce the overall dimension of equipment, reduces occuping in place, and simple structure.

Description

High-speed ultraviolet laser cutting FPC device of two mirrors that vibrate

Technical Field

The utility model relates to a FPC equipment technical field, in particular to high-speed ultraviolet laser cutting FPC device of two mirrors that vibrate.

Background

The FPC is a Flexible Printed Circuit (FPC) made of polyimide or polyester film as a base material, and has high reliability and excellent flexibility. The high-density light-weight LED lamp has the characteristics of high wiring density, light weight, thin thickness and good bending property. The ultraviolet laser FPC cutting equipment adopts ultraviolet laser to cut FPC materials, utilizes the characteristics of ultraviolet light, has higher precision and better cutting effect than the traditional long wavelength cutting machine, and utilizes a high-energy laser source and an accurate control laser beam to effectively improve the processing speed and obtain more accurate processing results.

At present, the traditional ultraviolet laser FPC cutting equipment for example adopts a mechanical structure driven by XY motion axes, the external dimension of the traditional ultraviolet laser FPC cutting equipment is large, the material changing of different products is inconvenient, the cutting precision is low, the cutting efficiency is low, the processing cost is high, and the structure is very complex.

SUMMERY OF THE UTILITY MODEL

The utility model discloses the main technical problem who solves provides a two high-speed ultraviolet laser cutting FPC devices of mirror that shakes, its appearance size is little, the convenience reloads the product of difference, and cutting accuracy is high, cuts efficiently, and can realize two cutting simultaneously, simple structure.

In order to solve the problems, the utility model provides a double-vibrating-mirror high-speed ultraviolet laser FPC cutting device, which comprises a bracket, a feeding mechanism, a honeycomb panel platform, a smoking mechanism, a visual positioner, a laser cutting mechanism and a discharging mechanism; the support is provided with a marble platform and two rectangular columns; the feeding mechanism is provided with a left air inflation shaft, a right air inflation shaft, a left tension part, a right tension part and an air inflation shaft tensioner; the cellular board platform is provided with a left cellular board platform and a right cellular board platform; the visual positioner is provided with a first CCD visual positioner, a second CCD visual positioner, a third CCD visual positioner and a fourth CCD visual positioner; the laser cutting mechanism is provided with a laser platform, a left laser, a right laser, a left galvanometer, a right galvanometer, a left galvanometer component, a right galvanometer component, a motor lead screw motion component and a lead screw motion shaft; the motor lead screw motion assembly is provided with a motor; the laser platform is provided with a left square hole and a right hole; the discharging mechanism is provided with a left discharging groove and a right discharging groove; the left honeycomb plate platform and the right honeycomb plate platform are arranged in the center of the marble platform, and the smoking mechanism is arranged between the left honeycomb plate platform and the right honeycomb plate platform; the two rectangular columns are respectively arranged on the left side and the right side of the marble platform; the feeding mechanism is arranged behind the marble platform, the inflatable shaft tensioner is arranged between the left inflatable shaft and the right inflatable shaft, the left tension component is arranged in front of the left inflatable shaft, and the right tension component is arranged in front of the right inflatable shaft; the first CCD visual positioner and the second CCD visual positioner are respectively arranged on the left edge and the right edge of the left cellular board platform, and the third CCD visual positioner and the fourth CCD visual positioner are respectively arranged on the left edge and the right edge of the right cellular board platform; the discharging mechanism is arranged in front of the honeycomb plate platform, the left discharging groove corresponds to the left honeycomb plate platform, and the right discharging groove corresponds to the right honeycomb plate platform; the laser cutting mechanism is arranged at the top of the cuboid column, namely the laser platform is arranged at the top of the cuboid column, the left hole is right opposite to the left honeycomb panel platform, and the right hole is right opposite to the right honeycomb panel platform; the left laser is behind the left hole, and the right laser is behind the right hole; the motor lead screw motion assembly is arranged between the left hole and the right hole and is combined with the lead screw motion shaft; the left galvanometer is arranged below the left galvanometer component, and the right galvanometer is arranged below the right galvanometer component; the left side mirror that shakes is in the top of left hole, the right side mirror that shakes is in the top of right side hole, and the left side mirror that shakes, the right side mirror that shakes, the left side mirror assembly that shakes, the right side mirror assembly that shakes are on motor lead screw motion assembly.

Furthermore, the left air inflation shaft and the right air inflation shaft are used for placing FPC materials and respectively pass through the left tension component and the right tension component to reach the left honeycomb plate platform and the right honeycomb plate platform.

Further, the laser cutting mechanism is used for cutting FPC materials, namely a left laser emits laser to the left vibrating mirror assembly, the laser is emitted from the left vibrating mirror to cut the FPC materials on the left honeycomb board platform, and similarly, the right laser emits laser to the right vibrating mirror assembly, and the laser is emitted from the right vibrating mirror to cut the FPC materials on the right honeycomb board platform.

Further, the cut FPC material comes out from the left discharge chute and the right discharge chute.

Furthermore, the motor screw rod motion assembly can move along the screw rod motion shaft, so that the left galvanometer and the right galvanometer are driven to move.

Furthermore, the laser emitted by the left laser and the laser emitted by the right laser are ultraviolet laser, so that the FPC material can be accurately cut.

Furthermore, the first CCD visual locator, the second CCD visual locator, the third CCD visual locator and the fourth CCD visual locator are used for visual identification.

Furthermore, the height of the left cellular board platform and the height of the right cellular board platform can be adjusted.

Further, the smoking mechanism is used for sucking away smoke generated by cutting the FPC material.

The beneficial effects of the utility model reside in that: this design uses two lasers, realizes that two mirrors independently process FPC product function that shake, and each lens during operation that shakes does not influence each other, greatly promotes work efficiency, has cancelled the lens subassembly that shakes of traditional model by XY motion axis driven mechanical structure, can effectively reduce the overall dimension of equipment, reduces occuping in place, and simple structure.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a perspective view of the present invention.

Fig. 2 is a rear perspective view of fig. 1.

Fig. 3 is a left side view of fig. 1.

Fig. 4 is a right side view of fig. 1.

Fig. 5 is a rear view of fig. 1.

Fig. 6 is a top view of fig. 1.

The objects, features and advantages of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some embodiments, not all embodiments, of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

The first embodiment is as follows:

as shown in fig. 1 to 6, the double-vibrating-mirror high-speed ultraviolet laser cutting FPC device comprises a support 1, a feeding mechanism 2, a honeycomb panel platform 3, a smoking mechanism 4, a visual positioner 5, a laser cutting mechanism 6 and a discharging mechanism 7; the support 1 is provided with a marble platform 11 and two rectangular columns 12; the feeding mechanism 2 is provided with a left inflatable shaft 21, a right inflatable shaft 22, a left tension part 23, a right tension part 24 and an inflatable shaft tensioner 25; the cellular board platform 3 is provided with a left cellular board platform 31 and a right cellular board platform 32; the visual positioner 5 is provided with a first CCD visual positioner 51, a second CCD visual positioner 52, a third CCD visual positioner 53 and a fourth CCD visual positioner 54; the laser cutting mechanism 6 is provided with a laser platform 61, a left laser 62, a right laser 63, a left galvanometer 64, a right galvanometer 65, a left galvanometer assembly 66, a right galvanometer assembly 67, a motor screw rod movement assembly 68 and a screw rod movement shaft 69; the motor lead screw motion component 68 is provided with a motor; the laser platform 61 is provided with a left hole 611 and a right hole 612; the discharging mechanism 7 is provided with a left discharging groove 71 and a right discharging groove 72; the left cellular board platform 31 and the right cellular board platform 32 are arranged in the center of the marble platform 11, and the smoking mechanism 4 is arranged between the left cellular board platform 31 and the right cellular board platform 32; the two rectangular columns 12 are respectively arranged on the left side and the right side of the marble platform 11; the feeding mechanism 2 is arranged behind the marble platform 11, the inflatable shaft tensioner 25 is arranged between the left inflatable shaft 21 and the right inflatable shaft 22, the left tension part 23 is arranged in front of the left inflatable shaft 21, and the right tension part 24 is arranged in front of the right inflatable shaft 22; the first CCD visual locator 51 and the second CCD visual locator 52 are respectively arranged on the left side and the right side of the left cellular board platform 31, and the third CCD visual locator 53 and the fourth CCD visual locator 54 are respectively arranged on the left side and the right side of the right cellular board platform 32; the discharging mechanism 7 is arranged in front of the cellular board platform 3, and the left discharging groove 71 corresponds to the left cellular board platform 31, and the right discharging groove 72 corresponds to the right cellular board platform 32; the laser cutting mechanism 6 is arranged on the top of the cuboid column 12, namely the laser platform 61 is arranged on the top of the cuboid column 12, the left hole 611 faces the left cellular board platform 31, and the right hole 612 faces the right cellular board platform 32; the left laser 62 is behind the left hole 611 and the right laser 63 is behind the right hole 612; the motor lead screw motion assembly 68 is arranged between the left hole 611 and the right hole 612, and the motor lead screw motion assembly 68 is combined with the lead screw motion shaft 69; the left galvanometer 64 is arranged below the left galvanometer component 66, and the right galvanometer 65 is arranged below the right galvanometer component 67; the left galvanometer 64 is arranged above the left hole 611, the right galvanometer 65 is arranged above the right hole 612, and the left galvanometer 64, the right galvanometer 65, the left galvanometer component 66 and the right galvanometer component 67 are arranged on the motor screw rod motion component 68.

As shown in fig. 1 to 6, the left and right air shafts 21 and 22 are used for placing FPC materials, and pass through the left and right tension members 23 and 24, respectively, and onto the left and right honeycomb board platforms 31 and 32.

As shown in fig. 1 to 6, the laser cutting mechanism 6 is used for cutting the FPC material, that is, the left laser 62 emits laser onto the left galvanometer assembly 66, and the laser is emitted from the left galvanometer 64 to cut the FPC material on the left honeycomb panel platform 31, and similarly, the right laser 63 emits laser onto the right galvanometer assembly 67, and the laser is emitted from the right galvanometer 65 to cut the FPC material on the right honeycomb panel platform 32.

As shown in fig. 1 to 6, the cut FPC materials come out from a left discharging chute 71 and a right discharging chute 72.

As shown in fig. 1 to 6, the motor screw motion assembly 68 can move along the screw motion shaft 69, so as to drive the left galvanometer 64 and the right galvanometer 65 to move.

As shown in fig. 1 to 6, the laser emitted by the left laser 62 and the laser emitted by the right laser 63 are ultraviolet laser, which can precisely cut the FPC material.

As shown in fig. 1 to 6, the first CCD visual locator 51, the second CCD visual locator 52, the third CCD visual locator 53 and the fourth CCD visual locator 54 are used for visual recognition.

As shown in fig. 1 and 2, the left cellular board platform 31 and the right cellular board platform 32 can be adjusted in height.

As shown in fig. 1 to 4, the smoking mechanism 4 is used to smoke the smoke generated by cutting the FPC material.

The above embodiments are only used to illustrate the technical solution of the present invention, and not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: it is to be understood that modifications may be made to the above-described arrangements in the embodiments or equivalents may be substituted for some of the features of the embodiments without departing from the spirit or scope of the present invention.

Claims (9)

1. A double-vibrating-mirror high-speed ultraviolet laser FPC cutting device is characterized by comprising a support (1), a feeding mechanism (2), a honeycomb panel platform (3), a smoking mechanism (4), a visual positioner (5), a laser cutting mechanism (6) and a discharging mechanism (7);

the support (1) is provided with a marble platform (11) and two rectangular columns (12);

the feeding mechanism (2) is provided with a left inflatable shaft (21), a right inflatable shaft (22), a left tension part (23), a right tension part (24) and an inflatable shaft tensioner (25);

the cellular board platform (3) is provided with a left cellular board platform (31) and a right cellular board platform (32);

the visual positioner (5) is provided with a first CCD visual positioner (51), a second CCD visual positioner (52), a third CCD visual positioner (53) and a fourth CCD visual positioner (54);

the laser cutting mechanism (6) is provided with a laser platform (61), a left laser (62), a right laser (63), a left galvanometer (64), a right galvanometer (65), a left galvanometer component (66), a right galvanometer component (67), a motor lead screw motion component (68) and a lead screw motion shaft (69); the motor lead screw motion assembly (68) is provided with a motor; the laser platform (61) is provided with a left hole (611) and a right hole (612);

the discharging mechanism (7) is provided with a left discharging groove (71) and a right discharging groove (72);

the left honeycomb plate platform (31) and the right honeycomb plate platform (32) are arranged in the center of the marble platform (11), and the smoking mechanism (4) is arranged between the left honeycomb plate platform (31) and the right honeycomb plate platform (32); the two rectangular columns (12) are respectively arranged on the left side and the right side of the marble platform (11);

the feeding mechanism (2) is arranged behind the marble platform (11), the inflatable shaft tensioner (25) is arranged between the left inflatable shaft (21) and the right inflatable shaft (22), the left tension component (23) is arranged in front of the left inflatable shaft (21), and the right tension component (24) is arranged in front of the right inflatable shaft (22);

the first CCD visual positioner (51) and the second CCD visual positioner (52) are respectively arranged on the left side and the right side of the left cellular board platform (31), and the third CCD visual positioner (53) and the fourth CCD visual positioner (54) are respectively arranged on the left side and the right side of the right cellular board platform (32);

the discharging mechanism (7) is arranged in front of the cellular board platform (3), the left discharging groove (71) corresponds to the left cellular board platform (31), and the right discharging groove (72) corresponds to the right cellular board platform (32);

the laser cutting mechanism (6) is arranged on the top of the cuboid column (12), namely the laser platform (61) is arranged on the top of the cuboid column (12), the left hole (611) is aligned with the left honeycomb panel platform (31), and the right hole (612) is aligned with the right honeycomb panel platform (32); the left laser (62) is behind the left hole (611), the right laser (63) is behind the right hole (612); the motor lead screw motion assembly (68) is arranged between the left hole (611) and the right hole (612), and the motor lead screw motion assembly (68) is combined with the lead screw motion shaft (69); the left galvanometer (64) is arranged below the left galvanometer component (66), and the right galvanometer (65) is arranged below the right galvanometer component (67); the left galvanometer (64) is arranged above the left hole (611), the right galvanometer (65) is arranged above the right hole (612), and the left galvanometer (64), the right galvanometer (65), the left galvanometer component (66) and the right galvanometer component (67) are arranged on the motor screw rod movement component (68).

2. The double-galvanometer high-speed ultraviolet laser cutting FPC device according to claim 1, wherein the left air expanding shaft (21) and the right air expanding shaft (22) are used for placing FPC materials and respectively pass through a left tension part (23) and a right tension part (24) to a left honeycomb board platform (31) and a right honeycomb board platform (32).

3. The FPC cutting device by using the dual-vibrating-mirror high-speed ultraviolet laser as claimed in claim 2, wherein the laser cutting mechanism (6) is used for cutting FPC material, namely a left laser (62) emits laser onto a left vibrating mirror assembly (66), the laser is emitted from a left vibrating mirror (64) to cut the FPC material on the left honeycomb board platform (31), and similarly, a right laser (63) emits laser onto a right vibrating mirror assembly (67), and the laser is emitted from a right vibrating mirror (65) to cut the FPC material on the right honeycomb board platform (32).

4. The double-vibrating-mirror high-speed ultraviolet laser FPC cutting device according to claim 3, wherein the cut FPC material comes out of a left discharging groove (71) and a right discharging groove (72).

5. The FPC cutting device by using the dual-vibrating-mirror high-speed ultraviolet laser as claimed in claim 3, wherein the motor lead screw motion assembly (68) can move along a lead screw motion shaft (69), so as to drive the left vibrating mirror (64) and the right vibrating mirror (65) to move.

6. The device for cutting the FPC by the double-vibrating-mirror high-speed ultraviolet laser is characterized in that laser emitted by the left laser (62) and the right laser (63) is ultraviolet laser, and FPC materials can be cut accurately.

7. The double-vibrating-mirror high-speed ultraviolet laser cutting FPC device according to claim 1, wherein the first CCD visual locator (51), the second CCD visual locator (52), the third CCD visual locator (53) and the fourth CCD visual locator (54) are used for visual identification.

8. The double-vibrating-mirror high-speed ultraviolet laser cutting FPC device of claim 1, wherein the left honeycomb plate platform (31) and the right honeycomb plate platform (32) are adjustable in height.

9. The device for cutting FPC by using high-speed ultraviolet laser with double vibrating mirrors as claimed in claim 1, wherein the smoking mechanism (4) is used for sucking away smoke generated by cutting FPC material.

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