CN213531229U - Laser processing system - Google Patents

Abstract

The utility model discloses a laser processing system, it includes: a light source module; the processing path includes a first processing station located in the first processing region and a second processing station located in the second processing region; the moving mechanism is used for changing the relative position between the workpiece and the light source module; the control unit is coupled with the moving mechanism and the light source module and controls the moving mechanism and the light source module to enable the light source module to move relatively in the processing path and provide the light; the processing patterns comprise a first pattern and a second pattern adjacent to the first pattern. The visibility of split position between first pattern and the second pattern can be reduced, the machining efficiency of whole laser machining system also can be increased, laser machining's time is shortened.

Description

Laser processing system

Technical Field

The utility model relates to a radium-shine system of processing, especially a carry out radium-shine system of processing of pattern preparation in workpiece surface through radium-shine light.

Background

The laser processing technology is that after laser light is processed by an optical assembly consisting of a plurality of lenses to achieve high focusing, the modulated laser light is used on a workpiece to achieve the processing purposes of marking or carving and the like. When the existing laser processing device or system is used to process patterns on a workpiece, the situation that the patterns to be processed are too large to be processed at one time is often encountered, so that the laser processing of the patterns can be completed only by splitting the too large patterns into a plurality of areas and segmenting, however, the method of partitioning the patterns in a splicing manner greatly prolongs the processing time, and the quality of the patterns is affected by the appearance of seams in the form of a plurality of split line segments due to splitting on the finally processed patterns.

In view of the problems encountered by the above-mentioned laser processing techniques, the prior art provides some processing methods to improve the quality of the pattern. One of the methods is to arrange a high-speed scanning galvanometer (galvometer scanner) in an optical component of the existing laser processing system, and the high-speed scanning galvanometer can rotate at a high speed within a period of time to continuously change the irradiation direction of laser light, so that the laser processing range can be expanded. In addition, in the process of processing the pattern divided into a plurality of areas one by one, after one of the areas is processed, the whole laser processing module must be moved to another area to perform the operation of the next area, and the laser processing module is moved while being constantly accelerated or decelerated, which not only prolongs the operation time, but also easily causes the deviation of the machine platform, so that the pattern of each area after processing is distorted and deformed or overlapped to another area, and even the joint of the pattern of each area needs to be compensated and processed to be corrected. Therefore, there is still a need to provide a laser processing system to solve the above problems encountered by the prior art.

The preceding paragraphs are intended merely to aid in understanding the present invention, and thus, it is intended that the disclosures in the preceding paragraphs include those that do not constitute a prior art that is known to those of ordinary skill in the art. The disclosures in the preceding paragraphs do not represent any admission or any admission that the claimed subject matter is being considered as pertaining to one or more embodiments of the invention, but are generally known or recognized by those skilled in the art prior to the filing date of the present application.

Disclosure of Invention

The utility model aims to overcome the defects of the prior art and provide a laser processing system, which can reduce the visibility of the splitting position between each splitting pattern by controlling the splitting mode of the processing pattern; and the time of whole laser processing can be effectively shortened through the mobile mode of control light source module and the split mode of processing the pattern.

In order to achieve the above purpose, the utility model adopts the technical scheme that: a laser machining system for laser machining a surface to be machined of a workpiece to form a machined pattern, the surface to be machined including a first machined region and a second machined region adjacent to the first machined region, the machined pattern spanning the first machined region and the second machined region, the laser machining system comprising:

the light source module provides light rays to irradiate the surface to be processed, and the light source module provides the light rays to form the processing pattern when the light source module relatively moves along a processing path on the surface to be processed; the processing path includes a first processing station located in the first processing region and a second processing station located in the second processing region;

the moving mechanism is used for changing the relative position between the workpiece and the light source module; and

the control unit is coupled with the moving mechanism and the light source module, and controls the moving mechanism and the light source module to enable the light source module to move relatively in the processing path and provide the light; the processing patterns comprise a first pattern and a second pattern adjacent to the first pattern; the control unit controls the light source module to provide the light rays to form the first pattern on the surface to be processed when the first processing section moves relatively, and controls the light source module to provide the light rays to form the second pattern on the surface to be processed when the second processing section moves relatively;

the working pattern further comprises a pattern adjacent region located between and including at least a portion of the first pattern and at least a portion of the second pattern, the first pattern further comprises a plurality of first line segments in the pattern adjacent region, the second pattern further comprises a plurality of second line segments in the pattern adjacent region, the lengths of every two adjacent first line segments are different from each other, the lengths of every two adjacent second line segments are different from each other, one end of each first line segment, which is far away from the second pattern, forms a first boundary of the pattern adjacent region, one end of each second line segment, which is far away from the first pattern, forms a second boundary of the pattern adjacent region, and the sum of the length of each first line segment and the length of each second line segment adjacent to the first line segment is equal to the distance between the first boundary and the second boundary.

Preferably, the first boundary is parallel to the first processing station, the second boundary is parallel to the second processing station, and the first boundary is spaced from the second boundary by no more than 50% of the length of the first pattern in the first processing region in the direction perpendicular to the first processing station, and the first boundary is spaced from the second boundary by no more than 50% of the length of the second pattern in the second processing region in the direction perpendicular to the second processing station.

Optimally, the light source module is fixed on the moving mechanism, and the control unit controls the moving mechanism to drive the light source module to enable the light source module to move relatively in the processing path and provide the light.

Preferably, the moving mechanism further includes a movable workpiece supporting platform, the workpiece is disposed on the movable workpiece supporting platform, the control unit is coupled to the movable workpiece supporting platform, and the control unit controls the movable workpiece supporting platform to drive the workpiece so as to enable the light source module to move relatively in the processing path and provide the light.

Optimally, the light source module further comprises a laser light source, a first vibrating mirror, a second vibrating mirror and a focusing lens, wherein the light source module provides laser light through the laser light source and provides the light through the modulation of the first vibrating mirror, the second vibrating mirror and the focusing lens in sequence.

Preferably, the processing path further comprises connecting sections respectively connecting the first processing section and the second processing section, the first processing section being parallel to the second processing section; the control unit controls the light source module not to provide the light when the connecting section moves relatively. Further, the connecting section is a straight line section.

Optimally, the control unit controls the time for providing the light rays by the light source module to adjust the lengths of the first line segments and the second line segments.

Because of the application of the technical scheme, compared with the prior art, the utility model has the following advantages: the utility model provides a laser processing system, form first pattern and second pattern when carrying out relative movement along first processing section and second processing section respectively through the control light source module, the length inequality of each two adjacent first line segments and each two adjacent second line segments of processing pattern in the adjacent district of pattern in addition, and the length sum of the length of each first line segment and the second line segment that borders on this first line segment equals the interval on first border and second border, therefore can reduce the visuality of split position between first pattern and the second pattern after the processing pattern preparation is accomplished, also can increase whole laser processing system's machining efficiency, the time of laser processing shortens.

Drawings

Fig. 1 is a schematic diagram illustrating operation of a laser processing system according to an embodiment of the present invention;

FIG. 2 is a schematic diagram illustrating a structure of a light source module according to the embodiment of FIG. 1;

FIG. 3 is a top view of an adjacent area of a pattern according to the embodiment of FIG. 1;

fig. 4 is a schematic diagram illustrating operation of a laser machining system according to another embodiment of the present invention;

fig. 5 is a flowchart illustrating a laser processing method of a laser processing system according to yet another embodiment of the present invention.

Detailed Description

The invention will be further described with reference to examples of embodiments shown in the drawings.

The following description of the embodiments refers to the accompanying drawings, which are included to illustrate specific embodiments in which the invention may be practiced. Directional phrases used in the present disclosure, such as "upper," "lower," "front," "rear," "left," "right," "inner," "outer," "side," and the like, refer only to the orientation of the figure(s). Accordingly, the directional terminology is used for purposes of illustration and understanding, and is in no way limiting. In addition, in the description, unless explicitly described to the contrary, the word "comprise" or "comprises" should be understood to mean that including the element, but not excluding any other elements.

Fig. 1 is a schematic diagram illustrating an operation of a laser processing system according to an embodiment of the present invention, wherein XYZ coordinate axes are only used for illustrating the embodiment and are not used for limiting the scope of the present invention. Referring to fig. 1, a laser processing system 10 is used for laser processing a surface 20 to be processed of a workpiece to form a processing pattern 30. The laser processing system 10 includes a light source module 11, a moving mechanism 12 and a control unit 13, wherein the light source module 11 provides light 111 to irradiate the surface to be processed 20, the light 111 is laser light with proper power, and the light source module provides the light 111 while relatively moving along a processing path 24 on the surface to be processed 20 to form a processing pattern 30 on the surface to be processed 20. In detail, the surface to be processed 20 includes a first processing region 21 and a second processing region 22, the processing path 24 includes a first processing section 241 and a second processing section 242, wherein the first processing section 241 is located in the first processing region 21, the second processing section 242 is located in the second processing region 22, and the processing pattern 30 formed by the light 111 simultaneously spans the first processing region 21 and the second processing region 22. In addition, the surface to be processed 20 of the present embodiment is a plane, but not limited to this, the surface to be processed 20 may also have a plurality of recesses and protrusions.

With continued reference to fig. 1, the moving mechanism 12 is used to change the relative position between the workpiece and the light source module 11; the control unit 13 is coupled to the moving mechanism 12 and the light source module 11 respectively to control the moving mechanism 12 and the light source module 11 to move the light source module 11 on the processing path 24 relatively and control the light source module 11 to provide the light 111 at the same time. In detail, the workpiece is fixed and not moved, the light source module 11 is fixed to the moving mechanism 12, and the control unit 13 controls the moving mechanism 12 to drive the light source module 11 to move on the surface 20 to be processed of the workpiece, so as to present the above-mentioned relative movement of the light source module 12 on the processing path 24 and provide the light 111. A device or apparatus such as a robot arm or a slide mechanism suitable for moving in a direction parallel to the surface 20 to be processed, wherein the moving mechanism 12 is; the light source module 11 is fixed to the moving mechanism 12 by screws, tenons or other suitable means; the control Unit 13 is, for example, a Central Processing Unit (CPU), or other programmable general purpose or special purpose Microprocessor (Microprocessor), Digital Signal Processor (DSP), programmable controller, Application Specific Integrated Circuit (ASIC), or other similar components or combination of the above components, or a Personal Computer (PC), a Tablet PC, a mobile phone, or other electronic devices capable of performing remote connection control, and the present invention is not limited to the implementation components and methods of the fixing mode of the light source module 12 and the control Unit 13.

In an embodiment of the present invention, the processing pattern 30 formed by the light 111 includes a first pattern 31 and a second pattern 32 adjacent to the first pattern 31, when the control unit 13 controls the moving device 12 to make the light source module 11 perform a relative movement in the first processing section 241 of the processing path 24, the control unit 13 controls the light source module 11 to provide the light 111 to form the first pattern 31, and when the control unit 13 controls the moving device 12 to make the light source module 11 perform a relative movement in the second processing section 242 of the processing path 24, the control unit 13 controls the light source module 11 to provide the light 111 to form the second pattern 32. As shown in fig. 1, the processing pattern 30 in the present embodiment is, for example, a long stripe pattern, however, the processing pattern 30 may be any pattern or aspect that can be formed by laser processing.

Fig. 2 is a schematic diagram illustrating a structure of the light source module 11 according to the embodiment of fig. 1. Referring to fig. 1 and 2, the light source module 11 includes a laser light source 112, a first galvanometer 113, a second galvanometer 114, and a focusing lens 115. The laser light source 112 is, for example, a fiber laser light source, an ultraviolet laser light source, or other laser light sources capable of providing sufficient power; the first galvanometer 113 and the second galvanometer 114 are high-speed scanning galvanometers; the focusing lens 115 may be an F-theta lens (also known as a field flattener lens). In this embodiment, the light source module 11 provides the initial laser light through the laser light source 112, the first vibration mirror 113 and the second vibration mirror 114 are used to adjust the deflection direction of the initial laser light, for example, the first vibration mirror 113 controls the deflection of the light 111 in the X-axis direction, the second vibration mirror 114 controls the deflection of the light 111 in the Y-axis direction, and then the focusing lens 115 converges the deflected initial laser light. In this way, the initial laser light sequentially passes through the deflection of the first vibrating mirror 113 and the second vibrating mirror 114 and the modulation of the focusing lens 115 to form the light 111, and the processing pattern 30 formed by a plurality of mutually parallel laser scanning line segments can be formed on the surface 20 to be processed by the light 111.

Fig. 3 is a top view of an adjacent area of a pattern according to the embodiment of fig. 1. Please refer to fig. 1, fig. 2 and fig. 3, wherein the XYZ axes are only used for illustrating the present embodiment and are not used for limiting the scope of the present invention. Since the dimension of the processed pattern 30 exceeds the deflection limit of the first galvanometer 113 and the second galvanometer 114 in the light source module 11 to the light angle, the embodiment splits the processed pattern 30 into the first pattern 31 and the second pattern 32, for example, the split of the processed pattern 30 is planned by the existing CAD/CAM software and then input to the control unit 13, wherein the pattern adjacent region 33 is located between the first pattern 31 and the second pattern 32 and includes at least a part of the first pattern and at least a part of the second pattern 32. The processing pattern 30 is composed of a plurality of laser scanning line segments parallel to each other, so the first pattern 31 includes a plurality of first line segments 311 in the pattern adjacent region 33, the second pattern 32 also includes a plurality of second line segments 321 in the pattern adjacent region 33, wherein the lengths of each two adjacent first line segments 311 are different from each other, and the lengths of each two adjacent second line segments 321 are different from each other. In this way, in the adjacent pattern region 33, the edge of the first pattern 31 will be in an irregular shape due to the different lengths of the two adjacent first line segments 311, and the edge of the second pattern 32 will also be in an irregular shape due to the different lengths of the two adjacent second line segments 321, so that when the entire finished machined pattern 30 is viewed, the split part of the first pattern 31 and the second pattern 32 will be visually spliced without seams or overlapping, and even if a small-amplitude machining angle deviation occurs during machining of the laser machining system 10, the visual effect of the machined pattern 30 will not be affected.

In the adjacent pattern region 33, an end of each first line segment 311 adjacent to the first pattern 31 forms a first boundary 312 of the adjacent pattern region 33, and an end of each second line segment 321 adjacent to the second pattern 32 forms a second boundary 322 of the adjacent pattern region 33, wherein each first line segment 311 and each second line segment 321 are straight line segments. The adjacent pattern region 33 further includes a plurality of adjacent points 34, wherein an end of each first line segment 311 away from the first pattern 31 is adjacent to an end of another adjacent second line segment 321 away from the second pattern 32 at the adjacent point 34, and a sum of a length L311 of each first line segment 311 and a length L321 of the second line segment 321 adjacent to the first line segment 311 is equal to the distance D between the first boundary 312 and the second boundary 322, so that an irregular splitting position between the first pattern 31 and the second pattern 32, i.e., each adjacent point 34, is limited within the adjacent pattern region 33, and thus the irregular splitting position of the pattern is not too obvious for a viewer to visually, thereby reducing the visibility of the splitting position of the first pattern 31 and the second pattern 32 in the processed pattern 30.

Referring to fig. 1 and fig. 3, the first boundary 312 and the second boundary 321 of the pattern neighboring region 33 are not segments actually existing in the processing pattern 30, but are used for planning and controlling the lengths of the first segment 311 and the second segment 321 in the pattern neighboring region 33. The first boundary 312 is parallel to the first processing segment 241 of the processing path 24, and the second boundary 322 is parallel to the second processing segment 242 of the processing path 24, and in the present embodiment, the first processing segment 241 and the second processing segment 242 are arranged parallel to the X-axis direction. In addition, the first pattern 31 has a length L1 in the first processing region 21 in the direction perpendicular to the first processing stage 241, and the second pattern 32 has a length L2 in the second processing region 22 in the direction perpendicular to the second processing stage 242, wherein the distance D between the first boundary 312 and the second boundary 322 in the adjacent region 33 of the patterns is not more than 50% of the length L1, and the distance D is not more than 50% of the length L2. In the embodiment, the distance D, the lengths L1 and L2 are parallel to the Y-axis direction, and the distance D is less than 50% of the length L1 and less than 50% of the length L2, respectively, so that the splitting position between the first pattern 31 and the second pattern 32 can be controlled to be adjacent to the boundary between the first processing region 21 and the second processing region 22, and the light 111 emitted from the light source module 11 is not difficult to manufacture the first line segment 311 or the second line segment 321 of the adjacent pattern region 33. In addition, the first line segment 311 and the second line segment 321 are planned to be line segments parallel to the Y-axis direction, and since the processing pattern 30 is split into the first pattern 31 and the second pattern 32 and the light source module respectively provides the light source 111 along the first processing segment 241 on the first processing area 21 and the second processing segment 242 on the second processing area 22 for processing, the processing manner and the size design of the pattern adjacent area 33 can greatly reduce the number of the overall splitting positions of the processing pattern 30, thereby effectively shortening the overall laser processing time.

Referring to fig. 1 and fig. 3, the processing path 24 further includes a connection segment 243, the connection segment 243 respectively connects the first processing segment 241 and the second processing segment 242, wherein the first processing segment 241 is parallel to the second processing segment 242, and in the embodiment, the control unit 13 controls the light source module 11 and the moving mechanism 12 to make the light source module 11 move along the first processing segment 241, the connection segment 243 and the second processing segment 242 in sequence. Since the first processing stage 241 is parallel to the second processing stage 242, the difficulty of dividing the processing pattern 30 and the difficulty of designing the processing path 24 can be reduced. In addition, the connecting section 243 is a linear section, for example, a linear section parallel to the Y-axis direction in the embodiment, and the control unit 13 controls the light source module 11 not to provide the light ray 111 when the connecting section 243 moves relatively, so as to prevent the extra light ray 111 from interfering with the adjacent pattern area 33, so that the light source module 11 can move relatively to the second processing section 242 within the shortest time, and the operation time of the whole processing flow can be shortened. In addition, the present embodiment does not limit that the light source module 11 must move along the first processing section 241, the connecting section 243 and the second processing section 242 sequentially, and the light source module 11 and the moving mechanism 12 may be controlled to make the light source module 11 move along the second processing section 242, the connecting section 243 and the first processing section 241 sequentially to make the processing pattern 30, which is not limited to this embodiment.

With reference to fig. 1, fig. 2 and fig. 3, when the control unit 13 controls the light source module 11 to move relatively between the first processing section 241 and the second processing section 242, the control unit 13 controls the time of the light source module 11 providing the light 111 to adjust the lengths of the first line segments 311 and the second line segments 321, so as to achieve the split design of the processing pattern 30 into the first pattern 31 and the second pattern 32. In detail, in this embodiment, the lengths of each two adjacent first line segments 311 are different from each other, and the lengths of each two adjacent second line segments 321 are also different from each other, the control unit 13 may preset the lengths of each first line segment 311 and each second line segment 321, and may precisely control each first line segment 311 and each second line segment 321 to reach a predetermined length by controlling the light emitting and irradiating time of the laser light source 112 when the first galvanometer 113 and the second galvanometer 114 rotate.

The first processing section 241, the second processing section 242 and the connecting section 243 of the foregoing embodiments are linear segments, wherein the first processing section 241 and the second processing section 242 are planned to be parallel to the X-axis direction, and the first line 311 and the second line 321 are planned to be parallel to the Y-axis direction, however, the first processing section 241, the second processing section 242 and the connecting section 243 may also be planned to be non-linear segments according to the shape of the processing pattern 30, the first processing section 241 may be planned to be not perpendicular to the first line 311, and the second processing section 242 may be planned to be not perpendicular to the second line 321 to increase the flexibility of the pattern splitting plan. In addition, in the above embodiment, the processing pattern 30 is planned and split into the first pattern 31 and the second pattern 32, the processing pattern 30 spans the first processing region 21 and the second processing region 22, and the first pattern and the second pattern 32 are respectively manufactured along the first processing section 241 and the second processing section 242, however, the present invention can also plan a greater number of processing regions and processing paths according to the size of the processed pattern and the deflection angle of the first vibrating mirror and the second vibrating mirror in the light source module 11, and planning and dividing the processing pattern into a corresponding number of sub-patterns by the existing software to reduce the manufacturing difficulty of the processing pattern, wherein each sub-pattern is similar to the first or second pattern of the previous embodiment and is respectively positioned between two adjacent processing areas, the splitting manner, the processing manner and the achievable technical effect of each sub-pattern are substantially the same as those of the foregoing embodiments, and are not described herein again.

With reference to fig. 1, in another embodiment, the surface 30 to be processed further includes a third processing area 23, the processing path 24 further includes a third processing segment 244 and a connecting segment 245, two ends of the connecting segment 245 are respectively connected to the second processing segment 242 and the third processing segment 244, the processing pattern 30 formed by the light 111 further crosses over to the third processing area 23, that is, the processing pattern 30 is split into a first pattern 31, a second pattern 32 and a third pattern 35, and the number of the pattern adjacent regions 33 is 2, and the pattern adjacent regions are respectively located between the first pattern 31 and the second pattern 32, and between the second pattern 32 and the third pattern 35. That is, the manufacturing and pattern splitting method of the processed pattern 30 can flexibly correspond to the configuration of the laser processing system 10 or the deflection limit of each galvanometer in the light source module 11 to the light angle, and the processed pattern 30 can be split into 3 or more than 3 by the conventional CAD/CAM software planning, and the control unit 13 can also be configured to control the light source module 11 to perform relative movement in the second processing section 242 and simultaneously provide the light 111 to complete the manufacturing of the second pattern 31, and then control the light source module 11 to perform relative movement along the connecting section 245 to the third processing section 244 to continue providing the light 111 to continue the manufacturing of the third pattern 35 to complete the manufacturing of the processed pattern 30.

In addition, in this embodiment, the control unit 13 controls the light source module 11 and the moving mechanism 12 to make the light source module 11 move relatively along the first processing section 241, the connecting section 243, the second processing section 242, the connecting section 245 and the third processing section 244 in sequence, however, the control unit 13 may also control the light source module 11 and the moving mechanism 12 to make the light source module 11 move relatively along the third processing section 244, the connecting section 245, the second processing section 242, the connecting section 243 and the first processing section 241 in sequence to prepare the processing pattern 30, which is not limited to this. In addition, in the embodiment, the pattern adjacent region 33 is located between the first pattern 31 and the second pattern 32 and includes at least a portion of the first pattern 31 and at least a portion of the second pattern 32, and the pattern adjacent region 33 'is located between the second pattern 32 and the third pattern 35 and includes at least a portion of the second pattern 32 and at least a portion of the third pattern 35, wherein the form and the manufacturing method of the pattern adjacent region 33' are substantially the same as those of the pattern adjacent region 33, and are not repeated herein.

Fig. 4 is a schematic diagram illustrating an operation of a laser processing system according to another embodiment of the present invention, wherein XYZ axes are only used to illustrate the embodiment, and not to limit the scope of the present invention. Laser machining system 10A of the present embodiment is similar to laser machining system 10, and like components or devices are denoted by like reference numerals and are not described again. The difference between the laser processing system 10A and the laser processing system 10 is that the moving mechanism of the laser processing system 10A includes a movable workpiece supporting platform 14, the light source module 11 is held by a clamping tool 15, wherein the workpiece 200 is disposed on the movable workpiece supporting platform 14, so that the light source module 11 provides light 111 to the surface 20 to be processed for making the processed pattern 30. In this embodiment, the control unit 13 is further coupled to the movable workpiece supporting platform 14, and the control unit 13 controls the movable workpiece supporting platform 14 to drive the workpiece 200 so as to make the light source module 11 move relatively on the processing path (not shown in fig. 4) and provide the light 111. For example, the movable workpiece supporting platform 14 has a plurality of slide rails and can be driven by a motor system to move on a plane parallel to XY, the workpiece 200 is held by a clamp or a fastener so that the workpiece 200 does not move relative to the movable workpiece supporting platform 14, and the clamping tool 15 is a fixed cantilever so as to keep the position of the light source module 11 stationary, so that the movable workpiece supporting platform 14 drives the workpiece 200 so that the light source module 11 can move relative to each other along the processing path to implement the manufacturing of the processing pattern 30. Since the position of the light source module 11 is fixed and the movable workpiece supporting platform 14 moves the workpiece 200 to show the relative movement of the light source module 11 on the surface 20 to be processed, the light source module 11 can provide the light 111 with better output stability, thereby improving the final manufacturing quality of the processed pattern 30.

In addition, in another embodiment, the laser processing system 10A can also be provided with the moving mechanism 12 of the laser processing system 10, so that the relative movement of the light source module 11 on the processing path can be achieved by simultaneously matching the movement of the movable workpiece carrying platform 14, and since the light source module 11 and the workpiece 20 can simultaneously move in a square parallel to the XY plane, the manufacturing efficiency of the pattern 30 to be processed on the surface 20 to be processed can be improved.

Fig. 5 is a flowchart illustrating a laser processing method of the laser processing system according to still another embodiment of the present invention, in which the laser processing method in this embodiment can be implemented in cooperation with the laser processing system 10 or 10A of the previous embodiment, and the laser processing method includes the following steps. Referring to fig. 5 in conjunction with fig. 1, the surface to be processed 20 includes a first processing region 21 and a second processing region 22 adjacent to the first processing region 21, and the predetermined finished processing pattern 30 spans the first processing region 21 and the second processing region 22. Step S101: the light source module 11 is provided for providing light to irradiate the surface to be processed, wherein the light source module 11 provides light to form a processing pattern when moving relatively along a processing path of the surface to be processed, the processing path includes a first processing section located in a first processing area and a second processing section located in a second processing area, and the processing pattern includes a first pattern and a second pattern adjacent to the first pattern. In this step, the control unit 13 controls the light source module 11 to provide the light 111 to irradiate the surface 20 to be processed.

With continuing reference to fig. 5 in conjunction with fig. 1 or fig. 4, step S102: the light source module 11 is controlled to move relatively along the first processing segment and provide light to form a first pattern on the surface to be processed. In this step, the light source module 11 in the laser processing system 10 is fixed to the moving mechanism 12, and the moving mechanism 12 drives the light source module 11 to move relatively along the first processing section 241 without moving the surface 20 to be processed. In the laser processing system 10A, the workpiece 200 is disposed on the moving mechanism, i.e. the movable workpiece supporting platform 14, and the control unit 13 controls the movable workpiece supporting platform 14 to move, so that the light source module 11 moves along the first processing section relatively. The light source module 11 simultaneously provides light 111 to form the first pattern 31 on the first processing region 21.

With continuing reference to fig. 5 in conjunction with fig. 1 or fig. 4, step S103: the light source module 11 is controlled to move relatively along the connecting section connecting the first processing section and the second processing section so that the light source module 11 moves relatively to the second processing section, and the light source module 11 is controlled not to provide light when the connecting section moves relatively. In this step, the light source module 11 of the laser processing system 10 changes the moving direction by the moving mechanism 12 after the processing operation on the first processing section 241 is completed, and performs the relative movement along the connecting section 243, and in the laser processing system 10A, the movable workpiece supporting platform 14 changes the moving direction after the processing operation of the first processing section is completed by the light source module 11, so that the light source module 11 performs the relative movement along the connecting section. The control unit 13 also controls the light source module 11 not to provide the light 111 when moving along the connecting section 243 to the second processing section 242.

With continuing reference to fig. 5 and with reference to fig. 1, fig. 3, and fig. 4, step S104: the light source module 11 is controlled to move relatively along the second processing segment and provide light to form a second pattern on the surface to be processed so as to complete the processing pattern. In this step, the moving mechanism 12 of the laser processing system 10 drives the light source module 11 to move relatively along the second processing section 242 without moving the surface 20 to be processed; in the laser processing system 10A, the control unit 13 controls the movable workpiece supporting platform 14 to move, so as to move the light source module 11 relatively along the second processing section. The control unit 13 also controls the light source module 11 to provide the light 111 to form the second pattern 32 on the second processing region 22, so as to complete the manufacturing of the processing pattern 30.

According to the present invention, in the finished processing pattern 30 from step S101 to step S104, the adjacent pattern region 33 is located between the first pattern 31 and the second pattern 32 and at least includes a portion of the first pattern 31 and a portion of the second pattern 32, the first pattern 31 includes a plurality of first line segments 311 in the adjacent pattern region 33, the second pattern includes a plurality of second line segments 321 in the adjacent pattern region 33, the lengths of each two adjacent first line segments 311 are different from each other, the lengths of each two adjacent second line segments 321 are different from each other, wherein an end of each first line segment 311 remote from the second pattern 32 forms a first boundary 312 of the pattern adjacent region 33, an end of each second line segment 321 remote from the first pattern 31 forms a second boundary 322 of the pattern adjacent region 33, and the sum of the length L311 of each first segment 311 and the length L321 of the second segment 321 adjacent to the first segment 311 is equal to the distance D. The technical effect achieved by the laser processing method of the present embodiment is substantially the same as that of the foregoing embodiments, and will not be described herein again.

To sum up, the utility model discloses an among the radium-shine processing system, the processing pattern includes first pattern and the second pattern adjacent to first pattern, light source module 11 provides light when carrying out relative movement in first processing section and second processing section respectively with the first pattern and the second pattern in the formation processing pattern respectively, the length inequality of each two adjacent first line sections and each double-phase adjacent second line section of processing pattern in the adjacent district of pattern in addition, so can reduce the visuality of split position between first pattern and the second pattern after the processing pattern preparation is accomplished, also can increase the machining efficiency of whole radium-shine processing system, shorten radium-shine processing time.

The above embodiments are only for illustrating the technical concept and features of the present invention, and the purpose of the embodiments is to enable people skilled in the art to understand the contents of the present invention and to implement the present invention, which cannot limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered by the protection scope of the present invention.

Claims (8)

1. A laser machining system for laser machining a surface to be machined of a workpiece to form a machined pattern, the surface to be machined including a first machined region and a second machined region adjacent to the first machined region, the machined pattern spanning the first machined region and the second machined region, the laser machining system comprising:

the light source module provides light rays to irradiate the surface to be processed, and the light source module provides the light rays to form the processing pattern when the light source module relatively moves along a processing path on the surface to be processed; the processing path includes a first processing station located in the first processing region and a second processing station located in the second processing region;

the moving mechanism is used for changing the relative position between the workpiece and the light source module; and

the control unit is coupled with the moving mechanism and the light source module, and controls the moving mechanism and the light source module to enable the light source module to move relatively in the processing path and provide the light; the processing patterns comprise a first pattern and a second pattern adjacent to the first pattern; the control unit controls the light source module to provide the light rays to form the first pattern on the surface to be processed when the first processing section moves relatively, and controls the light source module to provide the light rays to form the second pattern on the surface to be processed when the second processing section moves relatively;

the working pattern further comprises a pattern adjacent region located between and including at least a portion of the first pattern and at least a portion of the second pattern, the first pattern further comprises a plurality of first line segments in the pattern adjacent region, the second pattern further comprises a plurality of second line segments in the pattern adjacent region, the lengths of every two adjacent first line segments are different from each other, the lengths of every two adjacent second line segments are different from each other, one end of each first line segment, which is far away from the second pattern, forms a first boundary of the pattern adjacent region, one end of each second line segment, which is far away from the first pattern, forms a second boundary of the pattern adjacent region, and the sum of the length of each first line segment and the length of each second line segment adjacent to the first line segment is equal to the distance between the first boundary and the second boundary.

2. The laser machining system of claim 1, wherein: the first boundary is parallel to the first processing station, the second boundary is parallel to the second processing station, and the first boundary is spaced from the second boundary by no more than 50% of the length of the first pattern in the first processing region in the direction perpendicular to the first processing station, and the first boundary is spaced from the second boundary by no more than 50% of the length of the second pattern in the second processing region in the direction perpendicular to the second processing station.

3. The laser machining system of claim 1, wherein: the light source module is fixed on the moving mechanism, and the control unit controls the moving mechanism to drive the light source module to enable the light source module to move relatively in the processing path and provide the light.

4. The laser machining system of claim 1, wherein: the moving mechanism further comprises a movable workpiece bearing platform, the workpiece is arranged on the movable workpiece bearing platform, the control unit is coupled with the movable workpiece bearing platform, and the control unit controls the movable workpiece bearing platform to drive the workpiece so as to enable the light source module to move relatively in the processing path and provide the light rays.

5. The laser machining system of claim 1, wherein: the light source module further comprises a laser light source, a first vibrating mirror, a second vibrating mirror and a focusing lens, wherein the laser light source provides laser light, and the light source module provides the laser light through the laser light source and sequentially provides the light through the modulation of the first vibrating mirror, the second vibrating mirror and the focusing lens.

6. The laser machining system of claim 1, wherein: the processing path further comprises connecting sections respectively connecting the first processing section and the second processing section, the first processing section being parallel to the second processing section; the control unit controls the light source module not to provide the light when the connecting section moves relatively.

7. The laser machining system of claim 6, wherein: the connecting section is a straight line section.

8. The laser machining system of claim 1, wherein: the control unit controls the time of the light source module for providing the light rays so as to adjust the length of each first line segment and each second line segment.

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