CN210937660U

CN210937660U - Center feeding laser system based on multiple optical fiber output laser modules and machining head

Info

Publication number: CN210937660U
Application number: CN201921319138.2U
Authority: CN
Inventors: 方强; 方笑尘
Original assignee: Individual
Current assignee: Individual
Priority date: 2019-08-14
Filing date: 2019-08-14
Publication date: 2020-07-07
Anticipated expiration: 2029-08-14

Abstract

The utility model discloses a center feeding laser system and a processing head based on a plurality of optical fiber output laser modules, which comprises a plurality of optical fiber output laser modules, a plurality of collimating lenses corresponding to the optical fiber output laser modules, a feeding pipe and a focusing lens with a through hole at the center; the plurality of optical fiber output laser modules are divided into several groups, the output optical fiber end face of each group of modules is arranged near the front focus of the corresponding collimating lens according to a certain rule, and the collimating lens at least comprises a lens; the focusing lens with the through hole in the center at least comprises a lens and is positioned behind the collimating lens; the feeding pipe penetrates through a central through hole of the focusing lens; the collimating lenses are arranged around the feeding pipe; the utility model discloses directly utilize the miniwatt module, avoided prior art to close the process of restrainting beam splitting again earlier, reduced equipment cost, only used a focusing lens in addition, the system debugging is simple.

Description

Center feeding laser system based on multiple optical fiber output laser modules and machining head

Technical Field

The utility model belongs to the technical field of laser, a laser system and utilize processing head of this system for laser beam machining is related to, especially a center pay-off laser system and processing head based on a plurality of optic fibre output laser module, but wide application in the laser beam machining industry.

Background

Sintering materials together is an important class of applications for laser processing, such as laser welding, laser cladding, and laser 3D printing. In laser 3D printing, the material sintered by this sintering process is usually sintering between powder and wire, and in welding and cladding, the sintering process is usually sintering between powder or wire and metal parts. According to the feeding mode and the beam irradiation mode of the sintering material, the current sintering technology can be divided into two types: one is a side feeding technique, i.e. sintering light is irradiated perpendicular to the sintering surface, and sintering materials are fed into an illumination area from the side; the other is a center feed technique, i.e. the material is fed vertically to the sintering surface and the sintering light irradiates the material and the sintering zone from all around. In contrast, the center feed technique can achieve simultaneous heating of the sintering materials (material and substrate) during sintering, generally resulting in better sintering quality, and in addition, the sintering laser head can move freely in all directions, which improves the flexibility of the manufacturing process.

Various embodiments have been proposed in the academia and industry for center feed technology. For example, chinese patent CN201711184987, a center powder feeding expandable multi-beam laser cladding head and application thereof; chinese patent CN201710790666 is a complete ring-shaped laser cladding head; chinese patent CN201710059713 laser cladding device; chinese utility model patent 201320761615.7 relates to a parallel annular laser cladding head. These patents show the implementation of center feed. For another example, chinese utility model patent 201510968684.9 discloses a laser head with a coaxial fuse and a laser coaxial fuse forming device; chinese utility model patent CN101386111A discloses a laser internal wire feeding device.

In the center-fed sintering technology, in order to reduce thermal stress, it is generally desirable that the sintering matrix can have a certain preheating and slow cooling, and the solution proposed by the laser cladding device of chinese patent CN201710059713 and the laser cladding device of chinese patent CN201610989297 based on the preheating and slow cooling of multifocal lenses.

In summary of all the published technical schemes of central feeding edge light illumination, the technical implementation paths can be summarized as the following steps: 1. splitting the laser beam into N parallel lights; 2. the N parallel lights are converged to the processing area through the N focusing lenses. In step 1, laser light comes from the same laser, and the light from the laser is collimated into parallel light and then divided into N beams by a beam splitter; for light from the fiber output laser, it is also split into N beams by a fiber beam splitter and then collimated into N beams by N collimating lenses.

In the field of laser processing, the used lasers are usually high-power lasers, the high-power lasers are expensive, in addition, the technology needs to solve the beam splitting problem of the high-power lasers, and the system is complex. In step 2, the optical axes of the N focusing lenses need to be tilted so that the optical axes intersect in the central feeding area. The system is difficult to debug, and the processing head structure is complex. In addition, after the laser processing system is designed, the structure of the processing light spot is fixed and cannot be adjusted to meet the requirements of different laser processing processes.

SUMMERY OF THE UTILITY MODEL

In order to solve the above-mentioned problem that exists among the prior art, the utility model aims at providing a center pay-off laser system and processing head based on a plurality of optic fibre output laser module, this system directly utilizes the miniwatt module, has avoided prior art to close the process of restrainting again, has reduced equipment cost. In addition, only one focusing lens is used, and the system is simple to debug. Finally, the structure of the light spot can be changed in real time in the processing process by independently controlling the low-power laser modules, so that the requirements of different laser processing technologies are met. By utilizing the system, the lighting sintering of the linear light spots on two sides of the center feeding can be realized, and the system is used in laser cladding processing and improves the cladding efficiency.

In order to realize the purpose, the utility model discloses a technical scheme is:

a center feeding laser system based on a plurality of optical fiber output laser modules is characterized by comprising a plurality of optical fiber output laser modules, a plurality of collimating lenses corresponding to the optical fiber output laser modules, a feeding pipe and a focusing lens with a through hole in the center; the plurality of optical fiber output laser modules are divided into several groups, the output optical fiber end face of each group of modules is arranged near the front focus of the corresponding collimating lens according to a certain rule, and the collimating lens at least comprises a lens; the focusing lens with the through hole in the center at least comprises a lens and is positioned behind the collimating lens; the feeding pipe penetrates through a central through hole of the focusing lens; the collimating lenses are arranged around the feeding pipe; the end faces of the optical fibers are overlapped near the rear focal plane of the focusing lens to form a composite light spot for laser processing after passing through the corresponding collimating lens and the focusing lens with the through hole at the center.

The optical axes of the collimating lenses are parallel to the optical axis of the focusing lens with the through hole in the center; the axis of the feeding pipe is superposed with the optical axis of the focusing lens with a through hole in the center.

The core diameters of the output fibers of the fiber output laser modules are the same or different; the output optical fiber output powers of the optical fiber output laser modules are the same or different; the wavelengths of the output light of the optical fiber output laser modules are the same or different; the focal lengths of the collimating lenses are the same or different.

By adjusting the position of the output end face of the output optical fiber of the optical fiber output laser modules, the size of the fiber core, the focal length of the collimating lens and the focal length of the focusing lens with the through hole in the center, the output end faces of the laser modules are superposed together through the corresponding collimating lens and the focusing lens with the through hole in the center.

By adjusting the position of the output end face of the output optical fiber of the optical fiber output laser modules, the size of the fiber core, the focal length of the collimating lens and the focal length of the focusing lens with the through hole in the center, images formed by the output end faces of the laser modules after passing through the corresponding collimating lens and the focusing lens with the through hole in the center are distributed along the direction of the optical axis.

The two collimating lenses are distributed on two sides of the feeding pipe, the optical axes of the two collimating lenses are parallel to the axis of the feeding pipe, the axes of the two collimating lenses and the axis of the feeding pipe are positioned on the same plane, and the axis of the focusing lens with the through hole in the center is superposed with the axis of the feeding pipe; the optical fiber output laser modules are divided into two groups, the end faces of the output optical fibers of each group are arranged into a straight line and are respectively positioned on the front focal plane of one corresponding collimating lens, the arrangement direction is vertical to the plane where the axes of the two collimating lenses are positioned, and the central position of the linearly arranged optical fiber end faces is superposed with the focal point; the output end face of the output optical fiber forms two light spots which are converged in a sheet shape and distributed in a linear shape through the imaging of the output end face of the output optical fiber after passing through the corresponding collimating lens and the focusing lens with the through hole in the center, and the two light spots are combined together.

The relative durations of light emission by the fiber output laser modules are the same or different; the power over the relative duration of time that the fiber output laser modules emit light is the same, or different; the relative durations of light emission by the fiber output laser modules are synchronous or asynchronous; the light spot structure with the light spot shape changing along with time is formed, and the requirements of different laser processing on the light spots are met.

A center feeding processing head based on a plurality of optical fiber output laser modules comprises a plurality of optical fiber output laser modules, a plurality of collimating lenses corresponding to the optical fiber output laser modules, a focusing lens with a through hole in the center, a feeding pipe, an optical fiber support, a collimating lens support, a focusing lens support and a tubular shell, wherein the focusing lens support is provided with a plurality of through holes;

the center of the optical fiber support is provided with a through hole for the feed pipe to pass through, and the end surface of the output optical fiber of the optical fiber output laser module is arranged around the through hole in the center of the optical fiber support; the center of the collimating lens bracket is provided with a through hole for the feed pipe to pass through, and the collimating lens and the output end face of the output optical fiber are correspondingly arranged on the collimating lens bracket; the focusing lens with the through hole in the center is fixed on the focusing lens bracket; the optical fiber support is fixed in the tubular shell and close to one end, and the optical fiber output end surface fixed on the optical fiber support faces the other end of the tubular shell; the collimating lens support is fixed in the tubular shell and is adjacent to the optical fiber support; the focusing lens support is fixed in the tubular shell and is adjacent to the collimating lens support; the feeding pipe penetrates through a central through hole in the optical fiber support, a central through hole in the collimating lens support and a through hole in the focusing lens with the central through hole and is fixedly connected with the collimating lens support and/or the optical fiber support; on the processing head, the light output by the optical fiber output laser module is converged to the vicinity of the back focal plane of the focusing lens with the through hole at the center after passing through the collimating lens corresponding to the light output by the optical fiber output laser module and the focusing lens with the through hole at the center; after the feeding pipe is connected with the feeder, various laser processing heads can be formed according to the technical requirements and are used for laser welding, laser cladding and laser 3D printing.

At least one surface of at least one lens in the focusing lenses with the through holes at the centers is attached to a corresponding lens frame which is processed by good heat conduction materials and has the same surface type on the focusing lens support, and the area corresponding to collimated light on the lens frame is hollow so that corresponding light beams can penetrate through the lens frame; the lens frame is provided with a central hole, the lens frame is provided with a central hole for passing through the feeding pipe, and the lens mounting structure can greatly increase the heat dissipation capacity of the lens.

Furthermore, after the feeding pipe is connected with the feeder, various laser processing heads can be formed according to the technical requirements and are used for laser welding, laser cladding and laser 3D printing.

Compared with the prior art, the utility model discloses following beneficial effect has at least: 1. the technical scheme that beams are firstly combined and then split in the prior art is avoided, the system is constructed by directly adopting the low-power laser module, the system is simple, the price of the unit power of the low-power optical fiber output laser module is usually not higher than 0.5 time of the price of the unit power of the high-power laser, and the cost can be greatly reduced; 2. the focusing lens with the through hole in the center is adopted, the existing structure that a plurality of focusing lenses are adopted is avoided, the system debugging is simple, the focusing lens can be conveniently designed into a zooming lens to increase the flexibility of the equipment, and in the traditional scheme, the zooming capability cannot be basically increased; 3. the structure of the processing light spot can be changed in real time according to requirements by independently controlling the small power modules.

Drawings

Fig. 1 is the utility model provides a central pay-off laser system's light path structure sketch map based on a plurality of optic fibre output laser module.

Fig. 2 is the utility model provides a central pay-off laser system based on a plurality of fiber output laser modules opens the range structure sketch map of the focusing lens that has the through-hole in collimating lens, conveying pipe and center when observing along the optical axis direction.

FIG. 3 is a schematic diagram showing an arrangement of the collimator lenses, the feed pipe, and the focusing lens having a through hole at the center thereof in an embodiment using two collimator lenses.

Fig. 4 is a schematic structural diagram of an embodiment in which the output fiber end faces of M fiber output laser modules are linearly arranged near the front focal plane of a corresponding collimating lens.

Fig. 5 is a structural diagram of a laser processing head using a center feed laser system based on a plurality of fiber output laser modules.

Fig. 6 is a schematic view of a focusing lens cooling structure. FIG. 6A is a schematic view of a focusing lens with a through hole in the center; FIG. 6B is a schematic side view of a corresponding portion of the lens frame corresponding to the lens of FIG. 6A; fig. 6C is a front view of a corresponding portion of the lens frame corresponding to the lens of fig. 6A.

Wherein: m-1, M-2, … and M-N respectively represent optical fiber output laser modules; CL-1, CL-2, … CL-i, … CL-M denote collimating lenses, respectively; FL represents a focusing lens with a through hole at the center, and FL-1 is one of the focusing lenses; SLG denotes a feed tube; OB1, …, OBM profile represents the collimator lens front focal plane; i denotes the rear focal plane of the focusing lens; GXJ denotes a fiber shelf; ZZZJ denotes a collimating lens holder; FLZJ represents a focusing lens bracket with a through hole in the middle, and FLJ-1A represents a partial structure of a certain lens frame on the focusing lens bracket; GZK denotes a tubular housing.

Detailed Description

The following describes in detail the center feeding laser system based on a plurality of optical fiber output laser modes and the laser processing head using the same according to the embodiments and the accompanying drawings.

As shown in fig. 1, for the utility model provides a central pay-off laser beam machining optical system's light path structure sketch map based on a plurality of optic fibre output laser module, open the focusing lens that has the through-hole including a plurality of optic fibre output laser module, M collimating lens, conveying pipe and the center that correspond with optic fibre output laser module. Wherein: the feeding pipe SLG penetrates through a central through hole of the focusing lens FL; m collimating lenses CL-1, CL-2, … and CL-M are arranged around the feeding pipe and in front of the focusing lens; the number of the fiber output laser modules M-1, M-2, … and M-N is more than or equal to the number M of the collimating lenses, and the output fiber end faces of the fiber output laser modules are singly or in combination arranged near the front focal points of the corresponding collimating lenses. In the system, after the end face of the output optical fiber of the optical fiber output laser module passes through a corresponding collimating lens, a focusing lens with a through hole at the center is imaged to be close to a back focal plane I to form a laser spot for laser processing.

The present invention provides a collimating lens, which comprises at least one lens, wherein the collimating lens is generally composed of a plurality of lenses according to specific technical requirements, and the collimating lens is an equivalent ideal lens diagram. The focusing lens with the through hole in the center at least comprises one lens, and generally, according to technical requirements, the focusing lens with the through hole in the center consists of a plurality of lenses, and the focusing lens in the figure is a schematic diagram of an ideal equivalent lens.

Fig. 2 is a schematic diagram of an arrangement structure of collimating lenses CL-1, CL-2, …, CL-M, a feeding tube SLG and a focusing lens FL with a through hole in the center when the center feeding laser system and the processing head based on a plurality of fiber output laser modules are observed along the optical axis direction. The distance between each collimating lens and the feeding pipe can be different and can be set according to requirements.

In this technical solution, generally, the optical axes of the collimating lenses are parallel and parallel to the optical axis of the focusing lens having a through hole at the center; the axis of the feeding pipe is coincident with the optical axis of the focusing lens.

In the technical scheme, the core diameters of the output optical fibers of the optical fiber output laser modules can be the same or different; the output optical fiber output powers of the optical fiber output laser modules can be the same or different; the wavelengths of the output light of the optical fiber output laser modules can be the same or different; the focal lengths of the collimating lenses may be the same or different. The material fed through the feed tube SLG may be in the form of powder or in the form of wire.

In the technical scheme, the output end faces of the laser modules are superposed together through corresponding collimating lenses and focusing lenses with through holes in the centers by adjusting the positions of the output end faces of the output optical fibers of the optical fiber output laser modules, the sizes of fiber cores, the focal length of the collimating lenses and the focal length of the focusing lenses with through holes in the centers. In the system, all the light spots can be the same in size or different in size, when the light spots are different in size, the light spots which are superposed together have a structure with large central power and small edge power, and the preheating and slow cooling functions in the machining process can be realized.

In the technical scheme, by adjusting the position of the output end face of the output optical fiber of each optical fiber output laser module, the size of a fiber core, the focal length of a collimating lens and the focal length of a focusing lens with a through hole in the center, images formed by the output end faces of the laser modules after passing through the corresponding collimating lens and the focusing lens with the through hole in the center are distributed along the direction of an optical axis. In the system, after different light spots focused on the optical axis are superposed, light spot structures with large central power and small edge power and different relative powers can be obtained at different positions of the optical axis, and the preheating and slow cooling functions in the processing process are realized.

In the technical scheme, a system for sheet feeding and laser irradiation heating at two sides can be realized, and one structure of the system is as follows: the two collimating lenses are distributed at two sides of the feeding pipe, the optical axes of the two collimating lenses are parallel to the axis of the feeding pipe, the axes of the two collimating lenses and the axis of the feeding pipe are positioned on the same plane, and the axis of the focusing lens with the center provided with the through hole is superposed with the axis of the feeding pipe; the fiber output laser modules are divided into two groups, the end faces of the output fibers of each group are arranged into a straight line and are respectively positioned on the front focal plane of one corresponding collimating lens, the arrangement direction is vertical to the plane where the axes of the two collimating lenses are positioned, and the central position of the linearly arranged fiber end faces is superposed with the focal point; the output end face of the output optical fiber forms two light spots which are converged in a sheet shape and distributed in a linear shape through the imaging of the output end face of the output optical fiber after passing through the corresponding collimating lens and the focusing lens with the through hole in the center, and the two light spots are combined together.

The laser system is used for sintering the flaky materials, can improve the sintering efficiency, and is suitable for laser cladding processing. The flaky distributed materials sent by the external feeder are sent into the linear light spot area through the slit-shaped channel in the feeding pipe, and then the strip-shaped sintering processing can be realized.

In the technical scheme, the adopted laser module can be a continuous optical module, a quasi-continuous optical module or a pulse laser module, namely the relative duration of the light emission of the optical fiber output laser modules can be the same or different; the power of the fiber output laser modules during the relative duration of light emission may be the same or different; the relative durations of light emission by the fiber output laser modules may or may not be synchronized. Through the combination of the parameters, a light spot structure with the light spot shape changing along with time can be formed, and the requirements of different laser processing technologies on the light spot are met.

Fig. 5 is a schematic diagram of a laser processing head utilizing the above-proposed center feed laser system based on multiple fiber output laser modules of the present invention. The device comprises a plurality of optical fiber output laser modules M-1, M-2, … and M-N, a plurality of collimating lenses CL-1, CL-2, … and CL-M corresponding to the optical fiber output laser modules, a focusing lens FL with a through hole at the center, a feeding pipe SLG, an optical fiber support GXJ, a collimating lens support ZZZJ, a focusing lens support FLZJ and a tubular shell GZK. Wherein: the center of the optical fiber bracket GXJ is provided with a through hole; the end faces of the output optical fibers of the optical fiber output laser modules M-1, M-2, … and M-N are fixed at the positions around the through holes on the optical fiber support GXJ; a through hole is formed in the center of the collimating lens support ZZZJ, and collimating lenses CL-1, CL-2, … and CL-M are fixed around the through hole; a focusing lens FL with a through hole at the center is fixed on a focusing lens bracket FLZJ; the optical fiber bracket GXJ is fixed in the tubular shell GZK and close to one end, and the optical fiber output end surface fixed on the optical fiber bracket GXJ faces the other end of the tubular shell; the collimating lens support ZZZJ is fixed in the tubular shell GZK and is adjacent to the optical fiber support GXJ; the focusing lens support FLZJ is fixed in the tubular shell GZK and is adjacent to the collimating lens support ZZZJ; the feeding pipe SLG penetrates through a central through hole in the optical fiber support GXJ, a central through hole in the collimating lens support ZZZJ and a through hole in the focusing lens FL with the central through hole, and is fixedly connected with one or two of the collimating lens support ZZZJ optical fiber supports GXJ. On the processing head, the optical fiber output laser modules M-1, M-2, … and M-N output light output by optical fibers and converge near the back focal plane of the focusing lens with the through hole at the center after passing through the corresponding collimating lenses CL-1, CL-2, … and CL-M and the focusing lens FL with the through hole at the center, and after connecting the feeding pipe with the feeder, various laser processing heads can be formed according to technical requirements and used for laser welding, laser cladding, laser 3D printing and the like.

In the processing head, at least one surface of at least one lens in the focusing lenses with the through holes at the centers is attached to a corresponding lens frame which is processed by good heat conduction materials and has the same surface type on the focusing lens support, and the area corresponding to collimated light on the lens frame is hollowed out to allow corresponding light beams to penetrate; the lens frame is provided with a central hole for the feeding pipe to pass through; the lens mounting structure can greatly increase the heat dissipation capacity of the lens and reduce the heat effect caused by strong laser. Fig. 6 is a schematic view of the mounting structure of a certain piece of the focusing lens and the corresponding portion of the lens frame. Fig. 6A is a schematic side and front view of a lens with a through hole in the center of a lens, and fig. 6B and 6C are schematic side and front views respectively showing the structures of the lens frame portions. The lens frame is made of a good heat conduction material, and red copper or aluminum is generally adopted for processing convenience. The surface type of the surface, which is attached to the lens, on the lens frame is the same as the surface of the lens, the part, which corresponds to the collimated light, on the lens frame is hollowed out, and the part, which corresponds to the feeding pipe, is also hollowed out. Because the heat conduction energy of the lens frame material is usually dozens of times of that of the lens material, the structure can effectively lead out the heat dissipation generated on the lens by the laser, and the stability of the lens is improved.

The utility model provides a center pay-off laser system's theory of operation based on a plurality of optic fibre output laser module is:

the light emitted from the output fibers of the N fiber output laser modules M-1, M-2, …, M-N is collimated by the corresponding collimating lenses CL-1, CL-2, …, CL-M, and then focused by the focusing lens FL with a through hole at the center and superimposed on the back focal plane of the focusing lens, and the material fed from the feeding tube SLG is heated and melted by the M beams of light at the periphery in the region fed to the vicinity of the back focal plane and then sintered on the surface of the substrate located in the vicinity of the focal plane.

The advantages of this processing scheme are: firstly, in the processing process, the movement direction of the processing head can be set arbitrarily according to the requirement. And secondly, the spot area is usually larger than the feeding area in the processing process, so that the material and the matrix can be heated simultaneously, and the sintering quality can be ensured.

Example 1: according to the utility model provides a central pay-off laser system's based on a plurality of optic fibre output laser module technical scheme the utility model discloses an in a specific embodiment, open the focusing lens that has the through-hole including 8 optic fibre output semiconductor laser module, 8 collimating lens, a conveying pipe and a center, wherein: the laser wavelength is 915 nm, the diameter of the optical fiber core is 200 microns, the numerical aperture is 0.22, and the output power is 400 watts; the focal lengths of the collimating lenses are divided into 2 groups, and the focal lengths are 20 mm and 10 mm respectively; the center is provided with a through hole, the focal length of the focusing lens is 200 mm, and the diameter of the central through hole is 11 mm; the outer diameter of the feeding pipe is 10 mm, and the axis of the feeding pipe is superposed with the axis of the focusing lens with a through hole in the center; all the collimating lens optical axes are parallel to each other and are parallel to the focusing lens optical axis, and are distributed on the periphery of the material conveying pipe SLG at equal angular intervals, and the collimating lens optical axes are positioned on the circumference which takes the focusing lens optical axis as the center and has the diameter of 26 mm; the two kinds of collimating lenses are alternately arranged. The system forms 4 light spots with the diameter of 2 mm and 4 light spots with the diameter of 4 mm on the back focal plane of the focusing lens, and the centers of the light spots are positioned on the back focal point of the focusing lens to form a processing light spot with the center, high power and low power at the edge of the light spot. The system can process powder fed by the feeding pipe and also can process filament fed by the feeding pipe, the processing head can move along any direction in a two-dimensional plane, and due to the auxiliary edge light spots, the processing light spots have the functions of preheating and slow cooling, and the thermal stress in the processing can be reduced in principle.

In this embodiment, 4 laser modules with a diameter of 2 mm corresponding to a light spot are used as a group of synchronous control, 4 laser modules with a diameter of 4 mm corresponding to a light spot are used as another group of synchronous control, and the power distribution of the central light spot relative to the edge light spots can be changed by adjusting the relative power of the two groups, so as to meet the requirements of different processing technologies.

Example 2: according to the utility model provides a central pay-off laser system's based on a plurality of optic fibre output laser module technical scheme the utility model discloses an in a specific embodiment, open the lens that assembles that has the through-hole including 8 optic fibre output semiconductor laser module, 8 collimating lens, a conveying pipe and a center, wherein: laser wavelength of 976 nm, optical fiber core diameter of 200 μm, numerical aperture of 0.22, and output power of 400W; the focal lengths of the collimating lenses are the same and are 20 mm; the center is provided with a through hole, the focal length of the focusing lens is 200 mm, and the diameter of the central through hole is 11 mm; the outer diameter of the feeding pipe is 10 mm, and the axis of the feeding pipe is superposed with the axis of the focusing lens with a through hole in the center; all the collimating lens optical axes are parallel to each other and are parallel to the focusing lens optical axis, and are distributed on the periphery of the material feeding pipe SLG at equal angular intervals, and the collimating lens optical axes are uniformly distributed on the circumference which takes the focusing lens optical axis as the center and has the diameter of 26 mm. The 8 collimating lenses are divided into two groups which are alternately arranged, images of one group of end faces are overlapped at a position 5 mm in front of a focus point by adjusting the position of the output optical fiber end face of the optical fiber laser module in front of the collimating lenses, and images of the other group of end faces are formed at a position 5 mm behind the focus point. The system forms a high-power edge 3.6 mm low-power light spot with the center being 2 mm at two image points, forms a processing light spot with the low power at the edge of the high-power light spot at the center on two middle areas, and the power distribution structure of the light spot can be changed along with the change of the position, thereby bringing processing convenience. The system can process powder fed by the feeding pipe and also can process filament fed by the feeding pipe, the processing head can move along any direction in a two-dimensional plane, and due to the auxiliary edge light spots, the processing light spots have the functions of preheating and slow cooling, and the thermal stress in the processing can be reduced in principle.

In the embodiment, the distribution takes 4 laser modules corresponding to two light spots as a group, each group is synchronously controlled, and the power distribution of the central light spot relative to the edge light spot can be changed by adjusting the relative power of the two groups, so as to meet the requirements of different processing technologies.

Example 3: according to the utility model provides a central pay-off laser system's based on a plurality of optic fibre output laser module technical scheme the utility model discloses an in a specific embodiment, open the lens that assembles that has the through-hole including 18 optic fibre output semiconductor laser module, 2 collimating lens, a conveying pipe and a center, wherein: laser wavelength of 915 nm, optical fiber core diameter of 105 microns, numerical aperture of 0.22 and output power of 150W; the focal lengths of the collimating lenses are the same and are 20 mm; the center is provided with a through hole, the focal length of the focusing lens is 200 mm, and the diameter of the central through hole is 13 mm; the 2 collimating lenses are parallel to the optical axis of the focusing lens and distributed at an angle of 180 degrees on the circumference of 26 mm in diameter on both sides of the feeding tube SLG with the optical axis of the focusing lens as the center, as shown in fig. 3; the outer diameter of the feeding pipe is 12.5 mm, a slit-shaped hole is formed in the feeding pipe, the size of the slit is 10 mm X1 mm, the axis of the feeding pipe is overlapped with the axis of a focusing lens with a through hole in the center, and the length direction of the slit is perpendicular to a plane formed by the optical axes of the two collimating lenses; the 18 optical fiber output semiconductor laser modules are divided into two groups, and the optical fiber output end faces of each group of 9 optical fiber output modules are arranged at the front focuses of the corresponding collimating lenses at intervals of 125 micrometers along the direction perpendicular to the plane where the optical axes of the two collimating lenses are located, as shown in fig. 4; each group of optical fibers forms a light spot with the length of 11 mm and the width of 1.05 mm near the back focal point of the focusing lens, and the two light spots are overlapped. The light spot formed by the system can be sintered by the linear powder fed near the image point or by the fed sheet material.

Example 4: according to the utility model provides an utilize center pay-off laser system's processing head technical scheme based on a plurality of optic fibre output laser module the utility model discloses an in a specific embodiment, including 36 wavelength be 915 optic fibre output semiconductor laser module, 6 wavelength 650 optic fibre output semiconductor laser module, 6 collimating lens, a conveying pipe, open focusing lens, an optical fiber support GXJ, a collimating lens support ZZZJ, an subassembly focusing lens support FLZJ and the tubulose casing GZK that have the through-hole in the center. Wherein: the power of 36 optical fiber output modules with the wavelength of 915 nanometers is 120 watts, the core diameter of the output optical fiber is 105 micrometers, the cladding diameter is 125 micrometers, and the numerical aperture is 0.22; the power of 6 optical fiber output laser modules with the wavelength of 650 nanometers is 2 watts, the core diameter of the output optical fiber is 105 micrometers, the cladding diameter is 125 micrometers, and the numerical aperture is 0.22; the focal length of the 6 collimating lenses is 20 mm, and the diameter of the lenses is 12 mm; the focal length of the focusing lens with a through hole in the center is 200 mm, the diameter of the central through hole is 11 mm, and the diameter of the lens is 40 mm; the fiber support GXJ is of a cylindrical structure, the diameter of the cylinder is 46 mm, the center of the cylinder is provided with a through hole with the diameter of 10 mm, and 6 through holes with the diameter of 375 micrometers are arranged on a cylindrical surface which takes the axis of the through hole as the center and has the diameter of 26 degrees at an angle interval of 60 degrees; the straight frame ZZZJ of the collimator is a disc-shaped structure, the diameter of the disc is 46 mm, the center of the disc is provided with a through hole with the diameter of 10 mm, and 6 through holes with the diameter of 11 mm are arranged on a cylindrical surface which takes the axis of the through hole as the center and has the diameter of 26 degrees at an angular interval of 60 degrees; the focusing lens bracket FLZJ is of a circular ring structure, and has an inner diameter of 40 mm and an outer diameter of 46 mm; the inside of the tubular shell is provided with a circular through hole with the diameter of 46 mm; all fiber output laser modules are divided into 6 groups, each group comprises modules with 6 wavelengths 915 and 1 module with 650 wavelengths, and output fibers with 6 wavelengths 915 in the output fibers of each group of modules are arranged around a fiber with 650 wavelengths and are arranged in a through hole with 375 micrometers in diameter on a fiber support; the outer cylindrical surface of the optical fiber support GXJ is fixedly connected with the inner hole of the tubular shell GZK and is positioned at one end of the tubular shell, and the optical fiber output end surface faces the other end of the tubular shell GZK; 6 collimating lenses are fixed in 6 through holes on a disc-shaped collimator straight frame ZZZJ, the outer edge of the disc-shaped collimator support ZZZJ is fixed with an inner hole of a tubular shell GZK, the disc-shaped collimator support ZZZJ is adjacent to an optical fiber frame, the distance between the disc-shaped collimator support ZZZJ and the optical fiber frame support is determined by the focal length of the lenses, and the focal point of each collimating lens is superposed with the end surface of the optical fiber at the center of the corresponding group of optical fibers on the optical fiber frame; the focusing lens with a through hole is fixed in an inner hole of the focusing lens bracket FLZJ, and the outer edge of the annular focusing lens bracket FLZJ is fixed with the inner hole of the tubular shell GZK and is adjacent to the collimator bracket ZZZJ; the feeding pipe SLG penetrates through the central same hole of the optical fiber support, the central through hole of the collimator support and the focusing lens with the central through hole, and is fixedly connected with the optical fiber support and the collimating lens support. The system forms a circular light spot with the diameter of 3.6 millimeters and the red light of 650 nanometers indicates on the focal plane behind the focusing lens, 6 light beams forming the light spot are shot into from the side surface and the feeding shaft in a direction with a certain included angle, and after a feeder is connected to a feeding pipe, the fed powder or silk material can be sintered. The laser welding device is used for laser welding, laser cladding, laser 3D printing and the like.

In this example, we designed an achromatic focusing lens with a focal length of 200 mm, consisting of two lenses, one facing collimated light being a biconvex lens made of quartz glass, the radii of curvature of the two faces being 42.6 and 38.08, respectively, and the lens thickness being 9 mm; the other lens is a biconcave lens made of F2 glass and spaced 4.5 mm from the biconvex lens, the radius of curvature of the surface close to the biconvex lens is 32.3, the thickness of the lens is 2 mm, and the radius of curvature of the other surface is 480.1 mm. Two collimating lenses were perforated with a 11 mm diameter hole centered at the apex of the lens. In order to cool the focusing lens well, we use 3 cooling lens frames made of red copper to clamp the two lenses. The first lens frame facing collimated light adopts a plano-concave structure shown in fig. 6B, the radius of curvature of a concave surface is 42.6, the thickness of the concave surface is 5 mm at the vertex, a hole with the diameter of 11.2 mm is formed at the vertex by taking the vertex as the center, so that the feeding pipe passes through the hole, the centers of other 6 through holes corresponding to the collimated light are uniformly distributed on the circumference with the diameter of 26 mm, and the diameter of the hole is 8.5 mm; the lens frames positioned in the central parts of the two lenses are made into concave-convex structures, the curvature radiuses of the surface shapes are respectively 38.08 and 32.3, the thickness of the vertex is 4.5 mm, a hole with the diameter of 11.2 mm is formed in the vertex, the centers of other 6 through holes corresponding to collimated light are uniformly distributed on the circumference with the diameter of 24.4 mm, and the diameter of the hole is 10 mm; the last lens frame is made into a convex-flat structure, the curvature radius of the drawing is 480.1, the thickness of the vertex is 5 mm, a hole with the diameter of 11.2 mm is formed in the vertex by taking the vertex as the center, the centers of other 6 through holes corresponding to collimated light are uniformly distributed on the circumference with the diameter of 21.2 mm, and the diameter of the hole is 7.1 mm. The lens mounting structure can effectively eliminate the thermal lens effect caused by laser.

The utility model provides a center pay-off laser system and utilize processing head of this system based on a plurality of optic fibre output laser module has simple structure, advantage with low costs. By utilizing the system, various light spots required in the current laser sintering process can be generated, and various processing requirements can be met. Utilize this utility model, can realize the real-time control of facula structure to satisfy different processing technology's requirement, this has not realized yet in prior art, has further expanded the throughput of laser sintering technique and has promoted the processing effect.

Claims

1. The central feeding laser system based on the plurality of optical fiber output laser modules is characterized by comprising a plurality of optical fiber output laser modules, a plurality of collimating lenses corresponding to the optical fiber output laser modules, a feeding pipe and a focusing lens with a through hole in the center; the plurality of optical fiber output laser modules are divided into several groups, the output optical fiber end face of each group of modules is arranged near the front focus of the corresponding collimating lens according to a certain rule, and the collimating lens at least comprises a lens; the focusing lens with the through hole in the center at least comprises a lens and is positioned behind the collimating lens; the feeding pipe penetrates through a central through hole of the focusing lens; the collimating lenses are arranged around the feeding pipe; the end faces of the output optical fibers of the optical fiber output laser modules are overlapped near the rear focal plane of the focusing lens to form a composite light spot for laser processing after passing through the corresponding collimating lens and the focusing lens with the through hole at the center.

2. The center-fed laser system based on multiple fiber output laser modules as claimed in claim 1, wherein the optical axes of the multiple collimating lenses are parallel and parallel to the optical axis of the focusing lens with a through hole in the center; the axis of the feeding pipe is superposed with the optical axis of the focusing lens with a through hole in the center.

3. The multiple fiber output laser module based center-fed laser system of claim 1, wherein the core diameters of the output fibers of the multiple fiber output laser modules are the same or different; the output optical fiber output powers of the plurality of optical fiber output laser modules are the same or different; the wavelengths of the output light of the output optical fibers of the plurality of optical fiber output laser modules are the same or different; the focal lengths of the plurality of collimating lenses are the same or different.

4. The center-fed laser system based on multiple fiber output laser modules as claimed in claim 1, wherein the multiple fiber output laser module output fiber end faces are overlapped together by adjusting the position of the output end face of the multiple fiber output laser module output fibers, the size of the fiber core, the focal length of the collimating lens and the focal length of the focusing lens with a through hole in the center, through the corresponding collimating lens and the focusing lens with a through hole in the center.

5. The system of claim 1, wherein the plurality of laser module output end faces are distributed along the optical axis direction by adjusting the position of the output end faces of the plurality of fiber output laser modules output fibers, the size of the fiber core, the focal length of the collimating lens, and the focal length of the focusing lens with a through hole in the center, and images formed by the plurality of laser module output end faces through the corresponding collimating lens and the focusing lens with a through hole in the center.

6. The central feeding laser system based on the multiple optical fiber output laser modules as claimed in claim 1, wherein the number of the collimating lenses is two, the collimating lenses are distributed on two sides of the feeding pipe, the optical axes of the two collimating lenses are parallel to the axis of the feeding pipe, the axes of the collimating lenses and the axis of the feeding pipe are located on the same plane, and the axis of the focusing lens with the through hole in the center is coincident with the axis of the feeding pipe; the optical fiber output laser modules are divided into two groups, the end faces of the output optical fibers of each group are arranged into a straight line and are respectively positioned on the front focal plane of one corresponding collimating lens, the arrangement direction is vertical to the plane where the axes of the two collimating lenses are positioned, and the central position of the linearly arranged optical fiber end faces is superposed with the focal point; the output end face of the output optical fiber forms two light spots which are converged in a sheet shape and distributed in a linear shape through the imaging of the output end face of the output optical fiber after passing through the corresponding collimating lens and the focusing lens with the through hole in the center, and the two light spots are combined together.

7. The multiple fiber output laser module based center feed laser system of claim 1, wherein the relative durations of light emission of the multiple fiber output laser modules are the same or different; the power over the relative duration of light emission of the plurality of fiber output laser modules is the same, or different; the relative durations of light emission by the plurality of fiber output laser modules are synchronized or unsynchronized.

8. A machining head using the center feed laser system as claimed in claim 1, wherein: the device comprises a plurality of optical fiber output laser modules, a plurality of collimating lenses corresponding to the optical fiber output laser modules, a focusing lens with a through hole in the center, a feeding pipe, an optical fiber bracket, a collimating lens bracket, a focusing lens bracket and a tubular shell, wherein the collimating lens bracket is arranged in the tubular shell;

the center of the optical fiber support is provided with a through hole for the feed pipe to pass through, and the end surface of the output optical fiber of the optical fiber output laser module is arranged around the through hole in the center of the optical fiber support; the center of the collimating lens bracket is provided with a through hole for the feed pipe to pass through, and the collimating lens and the output end face of the output optical fiber are correspondingly arranged on the collimating lens bracket; the focusing lens with the through hole in the center is fixed on the focusing lens bracket; the optical fiber support is fixed in the tubular shell and close to one end, and the optical fiber output end surface fixed on the optical fiber support faces the other end of the tubular shell; the collimating lens support is fixed in the tubular shell and is adjacent to the optical fiber support; the focusing lens support is fixed in the tubular shell and is adjacent to the collimating lens support; the feeding pipe penetrates through a central through hole in the optical fiber support, a central through hole in the collimating lens support and a through hole in the focusing lens with the central through hole and is fixedly connected with the collimating lens support and/or the optical fiber support; on the processing head, light output by the optical fiber output laser module is converged to the vicinity of the back focal plane of the focusing lens with the through hole at the center after passing through the collimating lens corresponding to the light output by the optical fiber output laser module and the focusing lens with the through hole at the center.

9. The machining head of the center feed laser system as claimed in claim 8, wherein at least one surface of at least one of the lenses of the focusing lens with the through hole at the center is attached to a corresponding lens frame with the same surface type machined by the good heat conductive material on the focusing lens support, and the area corresponding to the collimated light on the lens frame is hollowed out to allow the corresponding light beam to pass through; the lens frame is provided with a central hole for passing through the feeding pipe.