阅读说明：本技术 一种激光加工设备的检测方法、装置、设备及存储介质 (Detection method, device and equipment of laser processing equipment and storage medium ) 是由 李海瑞 陈国栋 吕洪杰 翟学涛 于 2020-05-28 设计创作，主要内容包括：本发明实施例公开了一种激光加工设备的检测方法、装置、设备及存储介质。所述方法应用于激光加工设备,所述方法包括：获取测试文件,测试文件设有至少一个测试区域,测试文件包括多个预设图层,预设图层在每个测试区域设有对应的测试图案；根据预设图层和预设偏焦数据确定每个测试图案对应的预设偏焦距离；根据测试图案和预设偏焦距离,控制激光加工设备对测试工件进行激光加工；获取在加工后的测试工件上的切割线检测数据；根据切割线检测数据,确定与切割线检测数据对应的设备检测结果。本发明实现了自动化确定设备检测结果,减少操作人员的安全隐患,提高了激光加工精准检测的质量。(The embodiment of the invention discloses a detection method, a detection device, detection equipment and a storage medium of laser processing equipment. The method is applied to laser processing equipment, and comprises the following steps: acquiring a test file, wherein the test file is provided with at least one test area, the test file comprises a plurality of preset layers, and each preset layer is provided with a corresponding test pattern in each test area; determining a preset focus offset distance corresponding to each test pattern according to the preset image layer and the preset focus offset data; controlling laser processing equipment to carry out laser processing on the test workpiece according to the test pattern and the preset focusing distance; acquiring cutting line detection data on the processed test workpiece; and determining a device detection result corresponding to the cutting line detection data according to the cutting line detection data. The invention realizes the automatic determination of the detection result of the equipment, reduces the potential safety hazard of operators and improves the quality of the accurate detection of laser processing.)

1. A detection method of laser processing equipment is characterized by being applied to the laser processing equipment, and the method comprises the following steps:

acquiring a test file, wherein the test file is provided with at least one test area, the test file comprises a plurality of preset layers, and each preset layer is provided with a corresponding test pattern in each test area;

determining a preset focus offset distance corresponding to each test pattern according to the preset image layer and preset focus offset data;

controlling the laser processing equipment to carry out laser processing on the test workpiece according to the test pattern and the preset focusing distance;

acquiring cutting line detection data on the processed test workpiece;

and determining an equipment detection result corresponding to the cutting line detection data according to the cutting line detection data, wherein the equipment detection result comprises one or more of a laser focus position detection result, an equipment light path system detection result and/or a galvanometer XY two-axis motor detection result.

2. The inspection method of a laser processing apparatus according to claim 1, wherein the number of the test areas is 9;

9 test areas are arranged into a nine-square grid;

all the test patterns have the same specification, and the orientations of all the test patterns are the same;

and the target offset positions corresponding to the same preset image layer are the same, the target offset position refers to the offset position of a target test pattern relative to the central point of the test area corresponding to the target test pattern, and the target test pattern is any one test pattern.

3. The inspection method of a laser processing apparatus according to claim 1, wherein the test pattern includes one or more of a circular pattern, a zigzag pattern, and/or a square pattern;

the central points of all the graphs of the test pattern are overlapped;

when the test pattern simultaneously comprises the square graph and the meter-shaped graph, the vertex of the square graph is positioned on the line of the meter-shaped graph.

4. The method for detecting a laser processing apparatus according to claim 1, wherein said acquiring cutting line detection data on the test workpiece after processing, and determining an apparatus detection result corresponding to the cutting line detection data based on the cutting line detection data, comprises:

respectively obtaining cutting line widths corresponding to the test patterns on the processed test workpiece to obtain a plurality of pattern cutting line widths;

determining a minimum value from the plurality of pattern cutting line widths as a target cutting line width;

determining a target test pattern corresponding to the target cutting line width according to the target cutting line width;

determining a target preset focusing distance according to the target test pattern;

and determining the detection result of the laser focus position according to the preset focusing distance of the target.

5. The method for detecting a laser processing apparatus according to claim 4, wherein determining the detection result of the laser focus position at the preset focusing offset distance according to the target further comprises:

when the target preset offset focal distance is not equal to 0, adjusting the focal position of the laser processing equipment according to the detection result of the laser focal position, and executing the step of determining the preset offset focal distance of each test pattern according to the preset image layer and preset offset focal data;

and when the target preset focusing distance is equal to 0, taking the detection result of the laser focus position as the target focus position of the laser processing equipment.

6. The method for detecting a laser processing apparatus according to claim 1, wherein said acquiring cutting line detection data on the test workpiece after processing, and determining an apparatus detection result corresponding to the cutting line detection data based on the cutting line detection data, further comprises:

the number of the test areas is multiple, and the cutting line widths of the test patterns of the multiple test areas on the processed test workpiece are obtained respectively to obtain multiple pattern cutting line widths;

judging whether the pattern cutting line widths corresponding to the same preset image layer are consistent or not;

when the pattern cutting line widths corresponding to the same preset image layer are consistent, determining that the detection result of the equipment optical path system is normal;

and when the pattern cutting line widths corresponding to the same preset image layer are not consistent, determining that the detection result of the equipment optical path system is abnormal.

7. The method for detecting a laser processing apparatus according to claim 1, wherein said acquiring cutting line detection data on the test workpiece after processing, and determining an apparatus detection result corresponding to the cutting line detection data based on the cutting line detection data, further comprises:

the number of the test areas is multiple, and cutting line widths of target arcs of the test patterns of the multiple test areas on the processed test workpiece are obtained respectively to obtain multiple arc cutting line widths;

judging whether the cutting line widths of the arcs corresponding to the same preset image layer are consistent or not;

when the arc cutting line widths corresponding to the same preset image layer are consistent, determining that the detection result of the XY two-axis motor of the galvanometer is normal;

and when the arc cutting line widths corresponding to the same preset image layer are not consistent, determining that the detection result of the XY two-axis motor of the galvanometer is abnormal.

8. The method of inspecting a laser machining apparatus according to claim 1, further comprising:

the laser processing equipment is set to increase the distance between the focusing light spots, and the setting of increasing the distance between the focusing light spots comprises the following steps: increasing the scanning speed of a galvanometer of the laser processing equipment and/or reducing the pulse frequency of the laser processing equipment;

controlling the set laser processing equipment for increasing the distance between the focusing light spots to carry out laser processing on the test workpiece to obtain a plurality of non-overlapping focusing light spot cutting points;

acquiring shape data of the plurality of non-overlapping focusing light spot cutting points as focusing light spot detection data;

determining a roundness analysis result and an energy distribution analysis result of the focusing light spot according to the focusing light spot detection data;

and determining the laser spot detection result according to the roundness analysis result and the energy distribution analysis result.

9. A detection device of a laser processing device is characterized by being applied to the laser processing device, and the device comprises:

the test file acquisition module is used for acquiring a test file, the test file is provided with at least one test area, the test file comprises a plurality of preset layers, and each preset layer is provided with a corresponding test pattern in each test area;

the offset focus distance acquisition module is used for determining a preset offset focus distance corresponding to each test pattern according to the preset image layer and preset offset focus data;

the processing module is used for controlling the laser processing equipment to carry out laser processing on the test workpiece according to the test pattern and the preset focusing distance;

and the detection result determining module is used for acquiring cutting line detection data on the processed test workpiece and determining an equipment detection result corresponding to the cutting line detection data according to the cutting line detection data, wherein the equipment detection result comprises one or more of a laser focus position detection result, an equipment light path system detection result and/or a galvanometer XY two-axis motor detection result.

10. A storage medium storing a computer program of instructions which, when executed by a processor, causes the processor to carry out the steps of the method according to any one of claims 1 to 8.

11. A laser machining apparatus comprising at least one memory, at least one processor, the memory storing a program of computer instructions which, when executed by the processor, causes the processor to perform the steps of the method of any one of claims 1 to 8.

Technical Field

The present invention relates to the field of laser processing technologies, and in particular, to a method, an apparatus, a device, and a storage medium for detecting a laser processing device.

Background

In laser processing equipment, accurate detection of laser processing has been an industry difficulty. The laser focus position detection is an important detection factor for the accurate detection of laser processing, because the energy density of the laser focus position is high, the focus position is usually judged by the current method for searching the focus by shooting the laser on test paper to visually observe the focus or shooting the laser on a metal sheet to move back and forth to the Z-axis height according to the cut brightness or sound, the whole process is time-consuming and labor-consuming, certain potential safety hazards exist, for example, the test paper is easy to be moved to cause fire, and the metal sheet is utilized to cause the damage of eyes due to the high reflection of the laser intensity. Therefore, it is important to provide a detection method of a laser processing apparatus that is simple and safe to operate.

Disclosure of Invention

In view of the above, it is necessary to provide a method, an apparatus, a device and a storage medium for detecting a laser processing device.

In a first aspect, the present invention provides a method for detecting a laser processing apparatus, which is applied to a laser processing apparatus, and the method includes:

acquiring a test file, wherein the test file is provided with at least one test area, the test file comprises a plurality of preset layers, and each preset layer is provided with a corresponding test pattern in each test area;

determining a preset focus offset distance corresponding to each test pattern according to the preset image layer and preset focus offset data;

controlling the laser processing equipment to carry out laser processing on the test workpiece according to the test pattern and the preset focusing distance;

acquiring cutting line detection data on the processed test workpiece;

and determining an equipment detection result corresponding to the cutting line detection data according to the cutting line detection data, wherein the equipment detection result comprises one or more of a laser focus position detection result, an equipment light path system detection result and/or a galvanometer XY two-axis motor detection result.

In a second aspect, the present invention further provides a detection apparatus for a laser processing device, which is applied to a laser processing device, and the apparatus includes:

the test file acquisition module is used for acquiring a test file, the test file is provided with at least one test area, the test file comprises a plurality of preset layers, and each preset layer is provided with a corresponding test pattern in each test area;

the offset focus distance acquisition module is used for determining a preset offset focus distance corresponding to each test pattern according to the preset image layer and preset offset focus data;

the processing module is used for controlling the laser processing equipment to carry out laser processing on the test workpiece according to the test pattern and the preset focusing distance;

and the detection result determining module is used for acquiring cutting line detection data on the processed test workpiece and determining an equipment detection result corresponding to the cutting line detection data according to the cutting line detection data, wherein the equipment detection result comprises one or more of a laser focus position detection result, an equipment light path system detection result and/or a galvanometer XY two-axis motor detection result.

In a third aspect, the present invention also proposes a storage medium storing a computer program of instructions which, when executed by a processor, causes the processor to perform the steps of the method of any one of the first aspect.

In a fourth aspect, the present invention also proposes a computer device comprising at least one memory storing a computer program of instructions, at least one processor, which, when executed by the processor, causes the processor to carry out the steps of the method of any one of the first aspects.

In summary, according to the detection method, the detection device, the detection equipment and the storage medium of the laser processing equipment, the test file is obtained, the preset focusing distance corresponding to each test pattern is determined for the preset image layer and the preset focusing data of the test file, the cutting line detection data on the processed test workpiece is obtained, the equipment detection result corresponding to the cutting line detection data is determined according to the cutting line detection data, the equipment detection result comprises one or more of a laser focus position detection result, an equipment light path system detection result and/or a galvanometer XY two-axis motor detection result, the operation is simple, the automatic equipment detection result determination is realized, and the quality of the laser processing accurate detection is improved; the whole testing process does not need brightness or sound to judge the laser focus position, and does not need test paper and metal sheets, thereby reducing the potential safety hazard of operators; and the detection result of the optical path system of the equipment and the detection result of the XY two-axis motor of the galvanometer can be determined, so that the quality of the accurate detection of laser processing is further improved. Therefore, the invention realizes the automatic determination of the detection result of the equipment, reduces the potential safety hazard of operators and improves the quality of the accurate detection of laser processing.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only 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.

Wherein:

FIG. 1 is a schematic structural view of a laser processing apparatus according to an embodiment;

FIG. 2 is a flow chart of a method of inspection of a laser machining apparatus in one embodiment;

FIG. 3 is a schematic illustration of a plurality of test zones in one embodiment;

FIG. 4 is a schematic view of a test area in one embodiment;

fig. 5 is a flowchart of determining a detection result of a laser focus position of the detection method of the laser processing apparatus of fig. 2;

FIG. 6 is a flow chart of the result of the detection of the optical path system of the determining apparatus of the detection method of the laser processing apparatus of FIG. 2;

FIG. 7 is a flowchart of a result of determining the XY two-axis motor detection of the galvanometer of the detection method of the laser processing apparatus of FIG. 2;

FIG. 8 is a block diagram showing the structure of a detecting unit of the laser processing apparatus according to the embodiment;

FIG. 9 is a block diagram of a computer device in one embodiment.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The invention provides a detection method of laser processing equipment, which is applied to the laser processing equipment and can be used for accurately detecting the laser processing of the laser processing equipment.

As shown in fig. 1, the laser processing apparatus includes: a machining platform 102, a two-dimensional galvanometer and focusing lens arrangement 104; the two-dimensional galvanometer and focusing lens device 104 is disposed above the processing platform 102, and the workpiece to be processed is placed on the processing platform 102. The laser processing apparatus is used for laser processing a test workpiece (corresponding to a workpiece to be processed) placed on the processing platform 102. Such laser processing includes, but is not limited to: cutting by laser, drilling by laser. The test piece is a material that can be laser machined and can be polygonal in shape.

In order to improve the accuracy of the detection method of the laser processing apparatus, the test workpiece of the present invention employs a workpiece whose upper surface (surface close to the two-dimensional galvanometer) and lower surface (surface in contact with the processing platform 102) are parallel. It can be understood that the test workpiece of the present invention may also adopt a workpiece whose upper surface and lower surface are not parallel, at this time, the related data needs to be converted to the condition that the upper surface and lower surface of the test workpiece are parallel, and then the detection method of the laser processing apparatus of the present invention is adopted, which is not described herein again.

As shown in fig. 2, in one embodiment, the detection method of the laser processing apparatus includes:

s202, obtaining a test file, wherein the test file is provided with at least one test area and comprises a plurality of preset layers, and each test area of each preset layer is provided with a corresponding test pattern;

the test file may be imported into a program module for executing the detection method of the laser processing apparatus, or may be directly set in the program module for executing the detection method of the laser processing apparatus.

The test file is a file in which a test pattern is recorded. The test pattern is a pattern for laser processing by a laser processing apparatus, and includes at least one pattern composed of lines and/or dots. The test area is an area provided with a test pattern, and it can be understood that the test area is located within a processing range of a two-dimensional galvanometer of laser processing equipment when laser processing is performed according to a test file. The preset layer refers to a movable layer for placing test patterns in the test file. The preset image layer is arranged for quickly and consistently adjusting the preset focusing offset distance corresponding to the test pattern, for example, when the test pattern comprises a plurality of patterns, the preset focusing offset distance of the whole test pattern can be adjusted only by adjusting the preset focusing offset distance of the preset image layer, so that the preset focusing offset distance adjustment of each pattern of the test pattern can be avoided, the operation times are reduced, and the adjustment accuracy is improved; when the number of the test areas is at least two, the preset focusing offset distances of the test patterns of the preset image layers in all the test areas can be adjusted only by adjusting the preset focusing offset distances of the preset image layers, so that the adjustment of each test pattern corresponding to each test area is avoided, the operation times are reduced, and the consistency of the preset focusing offset distances of the test patterns of the same preset image layer can be realized.

It can be understood that the preset image layer can be set to conveniently and quickly set the distance between different test patterns in the test file.

Optionally, the test patterns in the same test area are located in different preset layers, so that different preset focusing distances can be set for the test patterns in the same test area.

The number of the test regions may be 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, which is not limited herein.

It will be appreciated that where the test file is provided with at least two test areas, there is no overlap between the test areas.

Optionally, when the test file is provided with at least two test areas, the number and layout manner of the test patterns in different test areas are the same, and the specifications and orientations of the test patterns in the same relative position in different test areas are the same. The test patterns at the same relative position refer to the test patterns at the same offset position (including abscissa and ordinate) from the center point of the test area where each test pattern is located. The same specification means that the components forming the test pattern are the same, and the sizes of the same components are the same; the orientation is the direction of the pattern in the test pattern. The layout mode is the arrangement position and the arrangement distance of the test patterns in each test area. For example, as shown in fig. 3, the number of the test areas is 9, the number of the test patterns in each test area is 9 (the number of the test patterns in different test areas is the same), the 9 test patterns in each test area are arranged in a grid of nine squares (the layout modes of the test patterns in different test areas are the same), and the offset positions of the center points of the test areas where the first test patterns in the upper left corner are respectively located are the same (9 test areas have 9 first test patterns that are the same relative position).

Optionally, the specifications and orientations of all the test patterns are the same, which is beneficial to quickly determining the equipment detection result according to the cutting line detection data of the laser-processed cutting line after laser processing is performed according to the test patterns.

Optionally, the test patterns at the same relative position are located in the same preset layer, so that the test patterns at the same relative position can be set to the same preset focusing distance quickly.

It can be understood that the preset focusing distances of different preset image layers may be the same or different.

S204, determining a preset focus offset distance corresponding to each test pattern according to the preset image layer and preset focus offset data;

the offset focal distance refers to a distance for offsetting the initial laser focus position of the laser processing equipment, and comprises an upper offset focal and a lower offset focal. The preset focusing distance refers to a preset focusing distance.

When debugging is carried out for the first time, because the specific numerical value of the laser focus position is unknown, the ideal laser focus position of the laser processing equipment can be used as the initial laser focus position of the laser processing equipment. The ideal laser focus position of the laser machining apparatus is a default position, such as a zero position.

Acquiring preset deflection data input by a user, determining a preset deflection distance corresponding to a preset image layer according to the preset deflection data, and taking the preset deflection distance of the preset image layer as a preset deflection distance corresponding to all test patterns on the preset image layer. For example, when debugging for the first time, it is assumed that the number of the preset image layers is 9 (L1 to L9), the preset bias data includes 800um, 600um, 400um, 200um, 0um, -200um, -400um, -600um, -800um, where (x0, y0) is an ideal laser focus position of the laser processing apparatus, and (x0, y0) is an initial laser focus position of the laser processing apparatus, and the positive number of the preset bias data is upper bias focus and the negative number is lower bias focus; then, the preset focus offset distance of the preset layer L1 corresponding to the test pattern is set to 800um, the preset focus offset distance of the preset layer L2 corresponding to the test pattern is set to 600um, the preset focus offset distance of the preset layer L3 corresponding to the test pattern is set to 400um, the preset focus offset distance of the preset layer L4 corresponding to the test pattern is set to 200um, the preset focus offset distance of the preset layer L5 corresponding to the test pattern is set to 0um, the preset focus offset distance of the preset layer L6 corresponding to the test pattern is set to-200 um, the preset focus offset distance of the preset layer L7 corresponding to the test pattern is set to-400 um, the preset focus offset distance of the preset layer L8 corresponding to the test pattern is set to-600 um, and the preset focus offset distance of the preset layer L9 corresponding to the test pattern is set to-800 um, which is not specifically limited in this example.

S206, controlling the laser processing equipment to carry out laser processing on a test workpiece according to the test pattern and the preset focusing distance;

and controlling the laser processing equipment to carry out laser processing on the test workpiece according to the test pattern and the preset focusing distance. When the preset focusing distance of the test pattern is equal to 0, laser processing is carried out by the laser processing equipment according to the initial laser focus position; when the preset focusing distance of the test pattern is not equal to 0, the initial laser focus position of the laser processing equipment is added with the preset focusing distance for laser processing, the value of the preset focusing distance can be used as a compensation value, the compensation value is added with the initial laser focus position of the laser processing equipment through program software of the laser processing equipment to obtain the compensated laser focus position of the laser processing equipment, and then the laser processing equipment performs laser processing according to the compensated laser focus position. Different compensated laser focus positions are determined through different preset focusing distances, and therefore the actual laser focus position of the laser processing equipment is found. For example, if the preset off-focal distance of the preset image layer L5 corresponding to the test pattern is set to 0um, the laser processing device performs laser processing at the initial laser focus position when the preset image layer L5 corresponding to the test pattern is processed; setting the preset focusing distance of the preset pattern layer L1 corresponding to the test pattern to 800um, performing upward focusing on 800um with the initial laser focus position as the reference point to obtain the compensated laser focus position, and performing laser processing on the compensated laser focus position (performing upward focusing on 800um with the initial laser focus position as the reference point) by the laser processing equipment when processing the preset pattern layer L1 corresponding to the test pattern, which is not specifically limited in this example.

Optionally, the machining platform 102 is an air suction platform, and the air suction platform sucks the test workpiece on the air suction platform through air suction to ensure that the test workpiece is parallel to the upper surface of the air suction platform.

It is understood that the number of test pieces may be one or more.

S208, acquiring cutting line detection data on the processed test workpiece;

the cutting line detection data can be obtained by measuring the cutting line on the processed test workpiece by using a high power microscope, and the cutting line detection data can also be determined by other means, for example, shooting an image by using a high power camera, and determining the cutting line detection data according to the image shot by the high power camera by using image analysis software.

The cutting line detection data comprises position data and line width detection results. The line width detection result is used for expressing the width of the cutting line.

S210, determining an equipment detection result corresponding to the cutting line detection data according to the cutting line detection data, wherein the equipment detection result comprises one or more of a laser focus position detection result, an equipment light path system detection result and/or a galvanometer XY two-axis motor detection result.

Specifically, the device detection result corresponding to the cutting line detection data is determined according to the position data and the line width detection result. Determining a laser focus position detection result according to all the line width detection results and all the position data; the number of the test areas is multiple, the cutting line widths of the test patterns of the multiple test areas corresponding to the processed test workpiece are respectively obtained, multiple pattern cutting line widths are obtained, and the detection result of the optical path system of the equipment is determined according to the pattern cutting line widths corresponding to the same preset image layer; the number of the test areas is multiple, the cutting line widths corresponding to the target arc lines of the test patterns in the multiple test areas on the processed test workpiece are obtained respectively, the cutting line widths of the multiple arc lines are obtained, and the detection result of the XY two-axis motor of the galvanometer is determined according to the cutting line widths of the arc lines corresponding to the same preset pattern layer.

The laser focus position detection result refers to the actual position of the laser focus. The detection result of the optical path system of the equipment refers to the detection result of the optical path system of the laser processing equipment, and comprises normal or abnormal results. The optical path system of the laser processing equipment refers to a part or a device used for transmitting laser from a laser to a two-dimensional galvanometer, and does not include the laser and includes the two-dimensional galvanometer.

And the detection result of the XY two-axis motor of the galvanometer comprises an X scanning motor detection result and a Y scanning motor detection result.

The cutting line width refers to the line width of a laser cutting line.

It can be understood that the accuracy of determining the detection result of the device can be improved by adjusting the interval between adjacent data of the preset out-of-focus data. For example, the interval between adjacent data of the preset focus offset data is adjusted from the interval 200 to the interval 100, and the accuracy of the device detection result obtained by the interval 100 is higher than that obtained by the interval 200, so that the accuracy of the device detection result can be improved.

In the embodiment, the test file is obtained, the preset offset focus distance corresponding to each test pattern is determined for the preset image layer and the preset offset focus data of the test file, the cutting line detection data on the processed test workpiece is obtained, and the equipment detection result corresponding to the cutting line detection data is determined according to the cutting line detection data, wherein the equipment detection result comprises one or more of a laser focus position detection result, an equipment light path system detection result and/or a galvanometer XY two-axis motor detection result, so that the operation is simple, the equipment detection result is automatically determined, and the quality of the laser processing accurate detection is improved; the whole testing process does not need brightness or sound to judge the laser focus position, and does not need test paper and metal sheets, thereby reducing the potential safety hazard of operators; and the detection result of the optical path system of the equipment and the detection result of the XY two-axis motor of the galvanometer can be determined, so that the quality of the accurate detection of laser processing is further improved.

As shown in fig. 3, in one embodiment, the number of test areas is 9; 9 test areas are arranged into a nine-square grid; all the test patterns have the same specification, and the orientations of all the test patterns are the same; and the target offset positions corresponding to the same preset image layer are the same, the target offset position refers to the offset position of a target test pattern relative to the central point of the test area corresponding to the target test pattern, and the target test pattern is any one test pattern. The cutting line detection data on the processed test workpiece can be acquired according to the laser processing result.

Optionally, the size of the squared figure formed by the test areas is smaller than or equal to the processing range of the two-dimensional galvanometer of the laser processing equipment, so that a part of test patterns cannot be processed by laser, and the quality of accurate detection of laser processing is further improved.

Optionally, the central point of one of the test areas overlaps with the central point of the processing range of the two-dimensional galvanometer of the laser processing device, so that the laser processing device is facilitated to carry out laser processing, and the efficiency of accurate detection of the laser processing is improved.

All the test patterns have the same specification, the orientations of all the test patterns are the same, and the target offset positions corresponding to the same preset pattern layer are the same, so that the rapid comparison and analysis of the cutting line detection data are facilitated, and the efficiency of the laser processing accurate detection is further improved.

As shown in fig. 3 and 4, in one embodiment, the test area includes 9 test patterns, 9 of which are arranged in a grid of nine squares; all the test patterns have the same specification, and the orientations of all the test patterns are the same; the distance between two adjacent test patterns is the same. The 9 test patterns are arranged into the Sudoku to facilitate laser processing of laser processing equipment, the specifications of all the test patterns are the same, and the orientations of all the test patterns are the same, so that rapid comparison and analysis of cutting line detection data are facilitated, and the efficiency of accurate detection of laser processing is further improved. The distance between two adjacent test patterns is the same, which is beneficial to simplifying the control of the laser processing equipment. For example, as shown in fig. 4, the number of the test regions corresponding to the preset layers is 9 (L1 to L9), each preset layer corresponds to one test pattern, and the L1L2 distance (the distance of L1L2 refers to the distance between the center point of the test pattern corresponding to L1 and the center point of the test pattern corresponding to L2), the L1L6 distance, the L7L6 distance, the L7L8 distance, the L9L8 distance, the L9L4 distance, the L3L4 distance, the L3L2 distance, the L6L5 distance, the L4L5 distance, the L8L5 distance, and the L2L5 distance are the same.

Optionally, the preset focusing distance of the test pattern at the center of the nine-grid cell is set to 0.

As shown in fig. 4, in one embodiment, the test pattern includes one or more of a circle pattern, a figure of a Chinese character 'mi' pattern, and/or a square pattern; the central points of all the graphs of the test pattern are overlapped; when the test pattern simultaneously comprises the square graph and the meter-shaped graph, the vertex of the square graph is positioned on the line of the meter-shaped graph. The circular graph comprises arc lines, the meter-shaped graph comprises a plurality of crossed lines, the square graph is a closed graph and is formed by vertically intersecting four straight lines in pairs, and one or more graphs in the circular graph, the meter-shaped graph and/or the square graph are combined into a test pattern, so that comparative analysis on cutting line detection data after laser processing is facilitated.

As shown in fig. 5, in an embodiment, the acquiring cutting line detection data on the processed test workpiece, and determining a device detection result corresponding to the cutting line detection data according to the cutting line detection data includes:

s502, obtaining a test file, wherein the test file is provided with at least one test area and comprises a plurality of preset layers, and each test area of each preset layer is provided with a corresponding test pattern;

s504, determining a preset focus offset distance corresponding to each test pattern according to the preset image layer and preset focus offset data;

s506, controlling the laser processing equipment to carry out laser processing on the test workpiece according to the test pattern and the preset focusing distance;

s508, respectively obtaining cutting line widths of the test patterns on the processed test workpiece, and obtaining a plurality of pattern cutting line widths;

optionally, the minimum value of the cutting line width in each processed pattern on the processed test workpiece is used as the pattern cutting line width of the test pattern corresponding to the processed pattern.

Optionally, the average value of the cutting line width in each processed pattern on the processed test workpiece is used as the pattern cutting line width of the test pattern corresponding to the processed pattern.

Optionally, since the preset focusing offset distance of each test pattern is the same, the width of any cutting line in the processed pattern obtained after the test pattern is processed on the processed test workpiece by laser can be used as the pattern cutting line width of the test pattern, so that the method for obtaining the pattern cutting line width is simplified.

It will be appreciated that each of the test patterns corresponds to a pattern cut line width.

S510, determining a minimum value from the plurality of pattern cutting line widths as a target cutting line width;

and determining a minimum value from the plurality of pattern cutting line widths, and taking the pattern cutting line width corresponding to the minimum value as a target cutting line width.

For example, the number of the preset layers is 9 (L1 to L9), 9 test regions are provided, and each preset layer corresponds to one test pattern in each test region, so that 81 test patterns can be obtained, 81 test patterns correspond to 81 pattern cut line widths, the minimum value is determined from the 81 pattern cut line widths, and the pattern cut line width corresponding to the minimum value is used as the target cut line width.

S512, determining a target test pattern corresponding to the target cutting line width according to the target cutting line width;

and taking the test pattern corresponding to the target cutting line width as a target test pattern corresponding to the target cutting line width.

S514, determining a target preset focusing distance according to the target test pattern;

and taking the preset focusing distance corresponding to the target test pattern as a target preset focusing distance.

S516, determining the detection result of the laser focus position according to the preset focusing distance of the target.

When the target preset focusing distance is equal to 0, taking the initial laser focus position of the laser processing equipment as a laser focus position detection result; and when the target preset focusing distance is not equal to 0, adding the target preset focusing distance to the initial laser focus position of the laser processing equipment to obtain a laser focus position detection result. For example, if the initial laser focus position of the laser processing apparatus is (x1, y1), and the target preset focusing distance is 200um, the initial laser focus position of the laser processing apparatus is set as a reference point, and the laser focus position detection result is obtained by performing upper focusing on 200 um.

In one embodiment, the determining the detection result of the laser focus position according to the preset focusing distance further includes: when the target preset offset focal distance is not equal to 0, adjusting the focal position of the laser processing equipment according to the detection result of the laser focal position, and executing the step of determining the preset offset focal distance of each test pattern according to the preset image layer and preset offset focal data; and when the target preset focusing distance is equal to 0, taking the detection result of the laser focus position as the target focus position of the laser processing equipment.

Specifically, when the target preset focusing distance is not equal to 0, adding the compensation value to the initial laser focus position of the laser processing device through the program software of the laser processing device to obtain a compensated laser focus position of the laser processing device, making the compensated laser focus position of the laser processing device the same as the detection result of the laser focus position, taking the compensated laser focus position of the laser processing device as the initial laser focus position of the next laser processing of the laser processing device, and executing the steps S504 to S516 for test verification. When the target preset focusing distance is equal to 0, it is indicated that the initial laser focus position of the laser processing equipment is correct at this time, so that the detection result of the laser focus position (which is also the initial laser focus position of the laser processing equipment) can be used as the target focus position of the laser processing equipment; and taking the target focus position as a final result of software focusing, and using the target focus position for laser processing production products of laser processing equipment. The whole process realizes software focusing, is beneficial to simplifying the control of the laser processing equipment, improves the accuracy of laser processing of the laser processing equipment and improves the quality of processed products.

As shown in fig. 6, in an embodiment, the acquiring cut line detection data on the processed test workpiece, and determining a device detection result corresponding to the cut line detection data according to the cut line detection data, further includes:

s602, obtaining a test file, wherein the test file is provided with at least one test area and comprises a plurality of preset layers, and each test area of each preset layer is provided with a corresponding test pattern;

s604, determining a preset focus offset distance corresponding to each test pattern according to the preset image layer and preset focus offset data;

s606, controlling the laser processing equipment to carry out laser processing on the test workpiece according to the test pattern and the preset focusing distance;

s608, the number of the test areas is multiple, and cutting line widths of the test patterns of the multiple test areas corresponding to the processed test workpiece are respectively obtained to obtain multiple pattern cutting line widths;

the number of the test areas is multiple, the cutting line widths of all the test patterns corresponding to all the test areas on the processed test workpiece are obtained, and the cutting line widths of the multiple patterns are obtained. For example, the number of the preset layers is 9 (L1 to L9), there are 9 test regions, and each preset layer corresponds to one test pattern in each test region, so that 81 test patterns can be obtained, and 81 test patterns correspond to 81 pattern cut line widths.

S610, judging whether the pattern cutting line widths corresponding to the same preset image layer are consistent or not;

and judging whether the pattern cutting line widths corresponding to all the test patterns on the same preset image layer are consistent or not.

It can be understood that the step of determining whether the cutting line widths of all the patterns corresponding to the same preset layer are consistent may be performed on the preset layers one by one.

S612, when the pattern cutting line widths corresponding to the same preset image layer are consistent, determining that the detection result of the equipment optical path system is normal;

because the preset focusing distances of the patterns corresponding to the same preset image layer are the same, under the condition that the equipment light path system of the laser processing equipment is set to be the same and normal, the laser processing equipment carries out laser processing with the same degree, and the most direct expression form of the laser processing with the same degree is that the cutting line width is the same. Therefore, when the pattern cutting line widths corresponding to the same preset layer are consistent, the detection result of the optical path system of the equipment can be determined to be normal.

And analyzing the preset image layers one by one, and determining that the detection result of the equipment optical path system is normal when the pattern cutting line widths corresponding to all the preset image layers are consistent. For example, the number of the preset layers is 9 (L1 to L9), the number of the test areas is 9, each preset layer corresponds to one test pattern in each test area, determining that the detection result of the optical path system of the device is normal when the pattern cut line widths of the 9 test patterns of L1 are consistent, the pattern cut line widths of the 9 test patterns of L2 are consistent, the pattern cut line widths of the 9 test patterns of L3 are consistent, the pattern cut line widths of the 9 test patterns of L4 are consistent, the pattern cut line widths of the 9 test patterns of L5 are consistent, the pattern cut line widths of the 9 test patterns of L6 are consistent, the pattern cut line widths of the 9 test patterns of L7 are consistent, the pattern cut line widths of the 9 test patterns of L8 are consistent, and the pattern cut line widths of the 9 test patterns of L9 are consistent, the pattern cutting line widths of the 9 test patterns are consistent, and the pattern cutting line widths of the 9 test patterns are all the same.

And S614, when the pattern cutting line widths corresponding to the same preset image layer are not consistent, determining that the detection result of the optical path system of the equipment is abnormal.

When the pattern cutting line widths corresponding to the same preset image layer are not consistent, the fact that the laser is not transmitted according to expectation by the optical path system of the equipment is indicated, and the laser deviates, and laser processing of different degrees is carried out in different test areas due to the deviation of the laser.

And analyzing the preset image layers one by one, and determining that the detection result of the equipment optical path system is abnormal when the pattern cutting line widths corresponding to the same preset image layer are inconsistent. For example, the number of the preset layers is 9 (L1 to L9), 9 test regions are provided, and each preset layer corresponds to one test pattern in each test region, so that when any one of pattern cut line widths of 9 test patterns of L1, pattern cut line widths of 9 test patterns of L2, pattern cut line widths of 9 test patterns of L3, pattern cut line widths of 9 test patterns of L4, pattern cut line widths of 9 test patterns of L5, pattern cut line widths of 9 test patterns of L6, pattern cut line widths of 9 test patterns of L7, pattern cut line widths of 9 test patterns of L8, pattern cut line widths of 9 test patterns of L9 are inconsistent, the detection result of the optical path system of the device is determined to be abnormal, where the pattern cut line widths of 9 test patterns are inconsistent and the pattern cut line widths of all the 9 test patterns are represented by the 9 test patterns.

According to the embodiment, the detection result of the optical path system of the equipment is determined according to the judgment of whether the cutting line width of the pattern corresponding to the same preset layer is consistent, so that debugging can be performed according to the detection result of the optical path system of the equipment in time, and the quality of a product processed by the laser processing equipment is further improved.

As shown in fig. 7, in an embodiment, the acquiring cut line detection data on the processed test workpiece, and determining a device detection result corresponding to the cut line detection data according to the cut line detection data, further includes:

s702, obtaining a test file, wherein the test file is provided with at least one test area and comprises a plurality of preset layers, and each test area of each preset layer is provided with a corresponding test pattern;

s704, determining a preset focus offset distance corresponding to each test pattern according to the preset image layer and preset focus offset data;

s706, controlling the laser processing equipment to carry out laser processing on the test workpiece according to the test pattern and the preset focusing distance;

s708, the number of the test areas is multiple, and cutting line widths, corresponding to the target arcs of the test patterns of the multiple test areas, on the processed test workpiece are respectively obtained to obtain multiple arc cutting line widths;

specifically, cutting line widths of the target arcs of all the test patterns corresponding to all the test areas on the processed test workpiece are obtained, and a plurality of pattern cutting line widths are obtained. Each test pattern corresponds to a target arc.

The target arc is a section of arc in the test pattern and can be a major arc, a minor arc and a semicircular arc, wherein the major arc is an arc larger than the semicircular arc, and the minor arc is an arc smaller than the semicircular arc.

Optionally, the arc is a 135 ° major arc, which facilitates accurate and rapid selection of the arc.

Optionally, the arc is a minor arc of 45 degrees, which is beneficial to accurately and quickly selecting the arc.

Optionally, the target arcs corresponding to the arc cutting line widths are arcs of the same type, where the same type refers to that the sizes of the arcs and the relative positions of the arcs in the test pattern are all the same. For example, the arcs are all upper semi-circles, or all lower semi-circles, or all 135 ° major arcs (arcs between 45 ° and 180 °), or all 45 ° major arcs (arcs between 0 ° and 45 °), which is not limited in this example.

S710, judging whether the cutting line widths of the arcs corresponding to the same preset image layer are consistent or not;

and judging whether the arc cutting line widths corresponding to the target arcs of all the test patterns on the same preset image layer are consistent or not.

It can be understood that the step of determining whether all the arc cutting line widths corresponding to the same preset layer are consistent may be performed on the preset layer one by one.

S712, when the arc cutting line widths corresponding to the same preset image layer are consistent, determining that the detection result of the XY two-axis motor of the galvanometer is normal;

the two-dimensional galvanometer is a two-dimensional scanning galvanometer, is a vector scanning device and comprises an X scanning motor, a Y scanning motor and an X-Y optical scanning head, and drives the X-Y optical scanning head to scan on an X-Y plane by driving the X scanning motor and the Y scanning motor so as to control the deflection of a laser beam on the X-Y plane.

When the arc cutting line widths corresponding to the same preset image layer are consistent, the X scanning motor and the Y scanning motor can be determined to deflect in a preset mode, and therefore the detection result of the X-axis motor and the Y-axis motor of the galvanometer can be determined to be normal.

And analyzing the preset image layers one by one, and determining that the detection result of the XY two-axis motor of the galvanometer is normal when the arc cutting line widths corresponding to all the preset image layers are consistent. For example, when the number of the preset layers is 9 (L1 to L9), 9 test areas are provided, and each preset layer corresponds to one test pattern in each test area, and the target arc is a semicircle on the test pattern, the arc cut line widths of the 9 test patterns of L1 are consistent, the arc cut line widths of the target arcs of the 9 test patterns of L2 are consistent, the arc cut line widths of the target arcs of the 9 test patterns of L3 are consistent, the arc cut line widths of the target arcs of the 9 test patterns of L4 are consistent, the arc cut line widths of the target arcs of the 9 test patterns of L5 are consistent, the arc cut line widths of the target arcs of the 9 test patterns of L6 are consistent, the arc cut line widths of the target arcs of the 9 test patterns of L7 are consistent, the arc cut line widths of the 9 test patterns of L8 are consistent, and the arc cut line widths of the target arcs of the 9 test patterns of L9 are consistent, and determining that the detection result of the vibrating mirror XY two-axis motor is normal, wherein the arc cutting line widths of the target arcs of the 9 test patterns are consistent, and the arc cutting line widths of the target arcs of the 9 test patterns are all the same.

S714, when the arc cutting line widths corresponding to the same preset image layer are not consistent, determining that the detection result of the XY two-axis motor of the galvanometer is abnormal.

When the arc cutting line widths corresponding to the same preset image layer are not consistent, the X scanning motor and/or the Y scanning motor do not deflect in a preset mode, so that laser deflection occurs, and laser deflection occurs, so that laser processing of different degrees is performed in different test areas.

Analyzing the preset image layers one by one, and determining that the detection result of the XY two-axis motor of the galvanometer is abnormal when the arc cutting line widths corresponding to the same preset image layer are inconsistent. For example, when the number of the preset layers is 9 (L1 to L9), 9 test areas are provided, and each preset layer corresponds to one test pattern in each test area, and the target arc is a semicircle on the test pattern, the arc cut line widths of the 9 test patterns of L1 are not uniform, the arc cut line widths of the target arcs of the 9 test patterns of L2 are not uniform, the arc cut line widths of the target arcs of the 9 test patterns of L3 are not uniform, the arc cut line widths of the target arcs of the 9 test patterns of L4 are not uniform, the arc cut line widths of the target arcs of the 9 test patterns of L5 are not uniform, the arc cut line widths of the target arcs of the 9 test patterns of L6 are not uniform, the arc cut line widths of the target arcs of the 9 test patterns of L7 are not uniform, the arc cut line widths of the target arcs of the 9 test patterns of L8 are not uniform, and the arc cut line widths of the target arcs of the 9 test patterns of L9 are not uniform, determining that the detection result of the vibrating mirror XY two-axis motor is abnormal, wherein the arc cutting line widths of the target arcs of the 9 test patterns are inconsistent, and the arc cutting line widths of the target arcs of the 9 test patterns are not all the same.

According to the embodiment, whether the arc cutting line width corresponding to the same preset image layer is consistent or not is judged, and the detection result of the XY two-axis motor of the galvanometer is determined, so that debugging can be performed timely according to the detection result of the XY two-axis motor of the galvanometer, and the quality of a product processed by the laser processing equipment is further improved.

In one embodiment, the method further comprises: the laser processing equipment is set to increase the distance between the focusing light spots, and the setting of increasing the distance between the focusing light spots comprises the following steps: increasing the scanning speed of a galvanometer of the laser processing equipment and/or reducing the pulse frequency of the laser processing equipment; controlling the set laser processing equipment for increasing the distance between the focusing light spots to carry out laser processing on the test workpiece to obtain a plurality of non-overlapping focusing light spot cutting points; acquiring shape data of the plurality of non-overlapping focusing light spot cutting points as focusing light spot detection data; determining a roundness analysis result and an energy distribution analysis result of the focusing light spot according to the focusing light spot detection data; and determining the laser spot detection result according to the roundness analysis result and the energy distribution analysis result.

The laser spot detection result comprises a focusing spot focusing effect detection result and a focusing spot energy distribution detection result.

The laser processing equipment is set to increase the distance between the focusing light spots, so that the laser processing equipment changes a cutting line of laser processing into a cutting point line (the point does not overlap with the point), and each point represents a cutting point of the focusing light spots.

It is to be understood that the laser processing apparatus after controlling the setting of increasing the pitch of the focused light spots performs laser processing on the test workpiece, which is not specifically limited herein, and may be a straight line, or the foregoing test pattern.

Acquiring shape data of the plurality of non-overlapping focused spot cut points as focused spot detection data, including: the high power microscope can be used for measuring a cutting point line on the processed test workpiece to obtain focusing light spot detection data, and other means can be adopted for determining the focusing light spot detection data, for example, a high power camera is adopted for shooting images, and image analysis software is adopted for determining the focusing light spot detection data according to the images shot by the high power camera.

And analyzing according to the focusing light spot detection data, determining that the focusing effect detection result of the focusing light spot is normal when the size of the circle of the maximum outline of the cutting point of the focusing light spot meets the expected size and the roundness of the circle of the maximum outline of the cutting point of the focusing light spot meets the expected roundness, and otherwise, determining that the focusing effect detection result of the focusing light spot is abnormal.

And analyzing according to the detection data of the focusing light spots, determining that the detection result of the energy distribution of the focusing light spots is normal when the capability distribution of the cutting points of the focusing light spots meets the expected energy distribution, and otherwise, determining that the detection result of the energy distribution of the focusing light spots is abnormal. For example, the expected energy is high (depth of cut) centered on the center point of the circle of the maximum profile of the cutting point of the focused spot, which is located on the surface of the test workpiece close to the two-dimensional galvanometer, low away from the center (depth of cut is inversely proportional to the distance away from the center), and is distributed symmetrically about the center point of the circle of the maximum profile of the cutting point of the focused spot (the projected pattern is close to a concentric circle when the cutting point of the focused spot is projected on the surface of the test workpiece close to the two-dimensional galvanometer).

The focusing effect and the energy distribution of the focusing light spots can be detected by improving the scanning speed of the galvanometer of the laser processing equipment and/or reducing the pulse frequency of the laser processing equipment, the operation is simple, and the quality of accurate detection of laser processing is further improved.

In one embodiment, before the obtaining the test file, the method further includes: and adjusting the focusing lens device to enable the X direction of the focusing lens device to be parallel to the X direction of the processing platform, and the Y direction of the focusing lens device to be parallel to the Y direction of the processing platform. Therefore, the distance between the focusing lens device and the upper surface of the processing platform during processing is the same, and the processing consistency of the laser processing equipment is improved.

Wherein, the X direction of the processing platform is vertical to the Y direction.

In one embodiment, the test workpiece may be adjusted to remain level on the processing platform. Specifically, as shown in fig. 1, the test workpiece may be placed on the processing platform 102, and the processing platform 102 is adjusted to uniformly adsorb the test workpiece, so as to ensure that the test workpiece can be kept horizontal under the action of adsorption, or the test workpiece may be kept horizontal on the processing platform 102 by an adsorption device or a fixing buckle. By adjusting the laser equipment in advance, the interference of hardware errors to the detection process can be eliminated when the laser equipment carries out laser processing, so that the detection result is more accurate.

In one embodiment, before the obtaining the test file, the method further includes: setting the distance between the focusing lens device and the processing platform as a preset focal length value, wherein the preset focal length value is a theoretical focal length value of a focusing lens of the focusing lens device. The distance between the focusing mirror and the processing platform is set to be a preset focal length value so as to eliminate the influence of the error of hardware equipment on the detection process.

As shown in fig. 8, in one embodiment, a detection apparatus for a laser processing device is provided, which is applied to the laser processing device, and the apparatus includes:

a test file obtaining module 802, configured to obtain a test file, where the test file is provided with at least one test area, the test file includes multiple preset layers, and each preset layer is provided with a corresponding test pattern in each test area;

a focus offset distance obtaining module 804, configured to determine a preset focus offset distance corresponding to each test pattern according to the preset layer and preset focus offset data;

a processing module 806, configured to control the laser processing device to perform laser processing on a test workpiece according to the test pattern and the preset focusing distance;

and the detection result determining module 808 is configured to obtain cutting line detection data on the processed test workpiece, and determine an equipment detection result corresponding to the cutting line detection data according to the cutting line detection data, where the equipment detection result includes one or more of a laser focus position detection result, an equipment optical path system detection result, and/or a galvanometer XY two-axis motor detection result.

The method comprises the steps of obtaining a test file, determining a preset deflection distance corresponding to each test pattern for the preset image layer and preset deflection data of the test file, obtaining cutting line detection data on the processed test workpiece, and determining an equipment detection result corresponding to the cutting line detection data according to the cutting line detection data, wherein the equipment detection result comprises one or more of a laser focus position detection result, an equipment light path system detection result and/or a galvanometer XY two-axis motor detection result, so that the operation is simple, the equipment detection result is automatically determined, and the quality of laser processing accurate detection is improved; the whole testing process does not need brightness or sound to judge the laser focus position, and does not need test paper and metal sheets, thereby reducing the potential safety hazard of operators; and the detection result of the optical path system of the equipment and the detection result of the XY two-axis motor of the galvanometer can be determined, so that the quality of the accurate detection of laser processing is further improved.

FIG. 9 is a diagram illustrating an internal structure of a computer device in one embodiment. The computer device may specifically be a terminal, and may also be a server. As shown in fig. 9, the computer device includes a processor, a memory, and a network interface connected by a system bus. Wherein the memory includes a non-volatile storage medium and an internal memory. The non-volatile storage medium of the computer device stores an operating system and may also store a computer program which, when executed by the processor, causes the processor to implement the method of detection of a laser machining device. The internal memory may also have a computer program stored therein, which, when executed by the processor, causes the processor to perform a method of detecting a laser machining apparatus. Those skilled in the art will appreciate that the architecture shown in fig. 9 is merely a block diagram of some of the structures associated with the disclosed aspects and is not intended to limit the computing devices to which the disclosed aspects apply, as particular computing devices may include more or less components than those shown, or may combine certain components, or have a different arrangement of components.

In one embodiment, the detection method of the laser processing device provided by the present application can be implemented in the form of a computer program, and the computer program can be run on a computer device as shown in fig. 9. The memory of the computer device can store program templates of the detection device of the laser processing device. For example, the test file acquiring module 802, the focusing distance acquiring module 804, the processing module 806, and the detection result determining module 808.

In one embodiment, a storage medium is proposed, storing a computer program of instructions which, when executed by a processor, causes the processor to carry out the following method steps when executed:

acquiring a test file, wherein the test file is provided with at least one test area, the test file comprises a plurality of preset layers, and each preset layer is provided with a corresponding test pattern in each test area; determining a preset focus offset distance corresponding to each test pattern according to the preset image layer and preset focus offset data; controlling the laser processing equipment to carry out laser processing on the test workpiece according to the test pattern and the preset focusing distance; acquiring cutting line detection data on the processed test workpiece; and determining an equipment detection result corresponding to the cutting line detection data according to the cutting line detection data, wherein the equipment detection result comprises one or more of a laser focus position detection result, an equipment light path system detection result and/or a galvanometer XY two-axis motor detection result.

In one embodiment, a laser machining apparatus is presented, comprising at least one memory, at least one processor, the memory storing a computer instruction program which, when executed by the processor, causes the processor to carry out the following method steps:

acquiring a test file, wherein the test file is provided with at least one test area, the test file comprises a plurality of preset layers, and each preset layer is provided with a corresponding test pattern in each test area; determining a preset focus offset distance corresponding to each test pattern according to the preset image layer and preset focus offset data; controlling the laser processing equipment to carry out laser processing on the test workpiece according to the test pattern and the preset focusing distance; acquiring cutting line detection data on the processed test workpiece; and determining an equipment detection result corresponding to the cutting line detection data according to the cutting line detection data, wherein the equipment detection result comprises one or more of a laser focus position detection result, an equipment light path system detection result and/or a galvanometer XY two-axis motor detection result.

It should be noted that, the above-mentioned detection method of a laser device, a detection apparatus of a laser device, a storage medium and a laser processing device belong to a general inventive concept, and the contents in the embodiments of a detection method of a laser device, a detection apparatus of a laser device, a storage medium and a laser processing device are mutually applicable.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by a computer program, which can be stored in a non-volatile computer-readable storage medium, and can include the processes of the embodiments of the methods described above when the program is executed. Any reference to memory, storage, database, or other medium used in the embodiments provided herein may include non-volatile and/or volatile memory, among others. Non-volatile memory can include read-only memory (ROM), Programmable ROM (PROM), Electrically Programmable ROM (EPROM), Electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), Dynamic RAM (DRAM), Synchronous DRAM (SDRAM), Double Data Rate SDRAM (DDRSDRAM), Enhanced SDRAM (ESDRAM), Synchronous Link DRAM (SLDRAM), Rambus Direct RAM (RDRAM), direct bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM).

The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, but should be considered as the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present application. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.