CN216028756U - Optical fiber laser welding head with swinging light spots - Google Patents

Abstract

The utility model relates to the technical field of laser processing, in particular to an optical fiber laser welding head with swinging light spots. It is characterized by comprising: the optical system comprises a collimating lens group, a deflection assembly and a focusing lens group; the control circuit comprises a control chip and a control loop, wherein the control loop comprises a sequential circuit, an oscillating circuit, a delay circuit and an operational amplification circuit; a drive system comprised of drive coils; the driving coils are oppositely arranged, and permanent magnets are arranged inside the driving coils; the driving coil is arranged on the torsion pendulum, and the torsion pendulum is fixedly connected with the deflection assembly and used for controlling light deflection; a mechanical support structure. The utility model greatly improves the welding quality, reduces the processing requirements of welding on the prior processes (such as cutting, blanking and the like), reduces the whole processing cost and improves the welding efficiency.

Description

Optical fiber laser welding head with swinging light spots

Technical Field

The utility model relates to the technical field of laser processing, in particular to an optical fiber laser welding head with swinging light spots.

Background

In the early laser welding, most of the laser welding is carried out by adopting a lamp-pumped solid laser, the output light spot of the laser is larger, the peak power is high, and a simple focusing welding head can complete the welding task. In recent years, the advantages of low cost and high stability of fiber lasers have gradually become an important light source option for laser welding. When the fiber laser is adopted, the fiber laser is continuously output, the peak power is not high, and the beam quality is high, so that the focusing light spot is small, the tolerance of the processing precision and the alignment precision of a workpiece is required to be improved through the track swing of the focusing light spot, and the welding quality is improved. The swinging light spot track can ensure that the metal melting liquid in the melting pool is fully stirred, and the splashing of plasma and the formation of defects such as bubbles, mixed crystals and the like in the welding process are reduced. A technique that employs this type of welding process is known as weaving welding.

The earliest wobbling of the laser spot was achieved by 2 galvanometers placed perpendicular to each other [ patent: US7282667B2, CN201012438Y ], are bulky, costly, and the vibration of the workpiece is strong, resulting in unstable welding quality. Subsequently, 2 relatively rotating wedge mirrors are developed to complete the operation of spot track swinging, but the defects of low spot swinging speed, short service life of a hollow motor and the like exist, and the spot track with a complex shape is not easy to realize. In addition, other spot swinging technologies such as rotating prism technology and magnetic suspension technology have been proposed, but the technology is complicated, so that the technology is only suitable for compact operation environments such as laboratories, and cannot be used in large-scale industrial environments.

SUMMERY OF THE UTILITY MODEL

The utility model provides an optical fiber laser welding head with swinging light spots, which can overcome the defects in the prior art and solve the problems of few use scenes, low light spot swinging speed, short service life of a hollow motor and low welding efficiency.

The specific technical scheme is as follows: an optical system (11), said optical system (11) comprising a collimating lens group (21), a deflecting assembly (22) and a focusing lens group (23); a drive system (14), said drive system (14) being comprised of a plurality of pairs of drive coils; any one pair of the driving coils are oppositely arranged, and a magnet is arranged inside each driving coil; the driving coil is arranged below the end part of the torsional pendulum, the magnet is coaxially arranged inside the driving coil, the driving coil and the torsional pendulum are connected through the magnet, and the magnet can move up and down along the central axis of the driving coil; the torsion pendulum (15) is fixedly connected with the deflection assembly and is used for controlling light deflection; a control circuit (13) for controlling the drive coil; a mechanical support structure (12) for supporting and connecting the focusing optical system (11), the control circuit (13), the drive system (14) and the torsional pendulum (15); .

Further, the control circuit (13) comprises a control chip (35) and a control loop; the control loop specifically comprises a sequential circuit (31), an oscillating circuit (32), a delay circuit (33) and an operational amplifier circuit (34);

further, the deflection component may specifically include a mirror, a refractive prism, or a grating;

furthermore, the torsion pendulum (15) is structured in such a way that a plurality of torsion springs are overlapped and staggered, and the first fixing point (451), the second fixing point (452) and the third fixing point (453) of the torsion springs are positioned in the same direction of the driving coil;

further, the torsion spring may be made of a steel spring sheet, a steel spring wire, a rubber spring, or an elastic composite material;

further, the collimating lens group may be a plano-convex lens or an aplanatic lens group;

further, the focusing lens group may be a plano-convex lens or an aspherical lens group.

The utility model has the beneficial effects that:

compared with the prior art, the utility model reduces the weight of the light spot control welding head by at least one half. In addition, because a driving circuit with large current is not needed, the circuit can be directly installed in the welding head, and the integrated design is realized. More importantly, the moving speed of the light spot track is only related to the Young modulus and the cross section of the torsion spring, and the motion inertia is only one thousandth of that of the motor, so that the swinging speed of 1kHz can be realized, which is 2-20 times of the swinging speed of a swinging welding head in the prior art, the welding quality is greatly improved, the processing requirements of welding on previous processes (such as cutting, blanking and the like) are reduced, the whole processing cost is reduced, and the welding efficiency is improved.

Drawings

The present invention will be described in further detail with reference to the following drawings and specific examples. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.

FIG. 1 is a structural diagram of an optical fiber laser welding head;

FIG. 2 is a schematic diagram of an optical system;

FIG. 3 is a schematic diagram of a control circuit;

FIG. 4 is a schematic view of a torsion pendulum structure;

FIG. 5 is a schematic view of the combination of the torsion pendulum, the lens and the electromagnet;

FIG. 6 is a schematic structural diagram of an embodiment of the present invention;

FIG. 7 is a schematic structural diagram of an embodiment of the present invention;

FIG. 8 is a schematic structural diagram of an embodiment of the present invention;

FIG. 9 is a schematic structural diagram of an embodiment of the present invention;

fig. 10 is a schematic view showing the combination relationship between the torsional pendulum and the driving coil.

Description of reference numerals:

11. a focusing optical system; 12. a mechanical support structure; 13. a control circuit; 14. a drive system; 15. swinging by torsion; 21. a collimating lens group; 22. a deflection assembly; 23. a focusing lens group; 24. a laser beam; 31. a sequential circuit; 32. an oscillation circuit; 33. a delay circuit; 34. an operational amplifier circuit; 35. a control chip; 41. a first torsion spring; 42. a second torsion spring; 43. a third torsion spring; 451-453 parts and spring fixing points; 46. swinging by torsion; 47. an optical lens; 48. driving an electromagnet; 51. a grip; 52. a central control chamber; 53. a front end output pipe; 54. a control circuit; 55. a drive coil; 56. swinging by torsion; 57. a deflection assembly; 58. a focusing lens; 59. a collimating system; 61. a quartz prism; 62. a connecting rod; 63. a spring; 64. a permanent magnet; 65. a drive coil; 71. an aplanatic lens group; 72. an aplanatic lens group; 73. a crescent lens; 74. swinging by torsion; 75. a drive coil; 83. swinging by torsion; 85. a mirror; 86. a focusing system.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. 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.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. The present invention will be described in further detail with reference to the accompanying drawings.

The utility model provides a light spot swinging optical fiber laser welding head, which comprises a focusing optical system 11, a mechanical supporting structure 12, a control circuit 13, a driving system 14, a torsion pendulum 15 and the like, wherein the mutual relation is shown in figure 1. The focusing optical system 11 is used for focusing the light beam output by the fiber laser on a working surface. The mechanical support structure 12 is used to support and connect the optical system, the electronic system and the torsion pendulum 15 system. The control circuit 13 provides the control logic of the circuit and controls the drive system 14. The drive system 14 provides magnetic attraction and repulsion forces. Under the driving of the driving system 14, the torsion pendulum 15 generates reciprocating swing by combining with the torsion of itself, and drives the optical member thereon to control the laser beam to realize the control of the light spot track.

The focusing optical system 11 is shown in fig. 2 and comprises a collimating lens group 21, a deflecting component 22 and a focusing lens group 23. The deflection assembly 22 may be constructed of either mirrors, or refractive prisms, or gratings, and combinations thereof. The deflection component 22 is fixed on the torsion pendulum 15, and the spot track control of the laser beam 24 is realized along with the swinging of the torsion pendulum 15.

The mechanical support structure 12 is a mechanical structure that provides support for all parts and combines them together, and can be mainly divided into optical system support, electronic support, torsion pendulum support, and other parts.

The control circuit 13 includes a control chip 35 and a plurality of control loops including a sequential circuit 31, an oscillation circuit 32, a delay circuit 33, and an operational amplifier circuit 34, as shown in fig. 3. The output signal of the delay circuit 33 is divided into two paths of signals, one of which is controlled by the timing circuit 31, and the outputs of the two operational amplifiers are kept at a certain phase angle through proper delay, so as to realize the pushing and pulling actions of the torsion pendulum 15. The control chip 35 can control groups of control loops to operate in parallel to control multiple drive coils.

In order to make the torsion pendulum swing at a set frequency, the current flowing through the coils at the two ends of the torsion pendulum needs to keep a phase difference of approximately 180 degrees, so as to form accurate 'pushing and pulling' of the torsion pendulum. In practical applications, the impedance of the torsion coil generally has a large tolerance. The control circuit has a function of automatically adjusting the phase difference. The control chip 35 determines the phase difference between the currents by measuring the current difference value flowing through the coils at the two ends of the torsion pendulum, and adjusts the current delay in the torsion pendulum coils by using the timing circuit 33 to make the current difference value be at the minimum value, thereby realizing the adjustment of the current phase.

The torsion pendulum 15 may be a torsion spring, or a spring steel sheet, or a spring steel wire, or a rubber elastic wire, or an elastic composite material, such as a carbon fiber composite material, one end of which is fixed to the base, and the other end of which is directly connected to the driving coil or a magnetic induction material, such as iron, is placed, so as to realize the reciprocating oscillation action in the back-and-forth "push-and-pull" action of the driving coil by combining the elastic force of the torsion pendulum itself, and the swinging part of the torsion pendulum is connected to the folding mirror or the lens in the system, thereby driving the regular reciprocating movement of the lens to realize the light spot swinging action.

Fig. 10 is a schematic view showing a combination relationship between a torsional pendulum 15 and a driving coil, wherein the driving coil is arranged below an end of the torsional pendulum, the magnet is coaxially arranged inside the driving coil, the driving coil and the torsional pendulum are connected through the magnet, and the magnet can move up and down along a central axis of the driving coil;

fig. 4 shows a three-dimensional torsion pendulum structure, which may also be a torsion pendulum with a one-dimensional or two-dimensional structure. The main body of the torsion pendulum is three torsion springs 41, 42, 43, and the material can be spring steel sheet, or spring steel wire, or rubber elastic wire, or elastic composite material. The torsion springs 41, 42, 43 in three dimensions are overlapped and staggered, and the direction of the dimension of the arrangement corresponds to the track direction of the expected control light spot. Wherein the third dimension torsion spring 43 is mounted on the second dimension torsion spring 42 and the second dimension torsion spring 42 is mounted on the first dimension torsion spring 41. The first fixing point 451, the second fixing point 452, and the third fixing point 453 of the spring are located in the same direction of the driving coil.

Fig. 5 shows an embodiment of the three-dimensional torsional pendulum 46, the optical lens 47 and the driving electromagnet 48. Wherein, the torsion pendulum comprises two sheets of manganese steel, and the thickness of the manganese steel sheet is 0.7 mm. The waist width was 5mm, cut into the shape shown in fig. 5, and placed at 90 degrees. And the manganese steel sheets are mutually connected at the central overlapped part through a welding process. The optical lens is adhered to the center of the second manganese steel sheet by glue. Four driving electromagnets with the diameter of 2mm are arranged at two ends of the swing arm.

According to the requirement of the dimension of the light spot track control, the driving system 14 can be composed of a plurality of pairs of driving coils, the driving system 14 corresponding to the number of the torsion pendulum in fig. 4 is also composed of 3 pairs of driving coils, and each pair of coils are oppositely arranged to realize the control of the light spot track of the dimension in the orthogonal direction. The driving coil is internally provided with a permanent magnet which generates magnetic attraction and magnetic repulsion to the torsion pendulum under the action of driving current.

The utility model is further illustrated by the following examples.

The first embodiment is as follows: one-dimensional control of facula track, handheld laser welding head

As shown in FIG. 6, the welding head in this embodiment is composed of a handle 51, a central control chamber 52, and a front output pipe 53. The collimating lens group 59 consists of a plano-convex lens (focal length 70 mm). The plano-convex lens is mounted in the grip. The focusing lens group 58 is composed of a plano-convex lens having a long focal length (focal length 300 mm). The focusing lens group 58 is mounted in the front output tube. A control circuit 54, a pair of drive coils 55, a torsional pendulum 56 and a deflection assembly 57 are mounted in the central control room. The deflection assembly 57 consists of a single 45 degree mirror. The torsion pendulum 56 adopts a No. 60 manganese steel sheet with the width of 2mm and the thickness of 1 mm. The two ends of the manganese steel sheet are tensioned, and the 45-degree reflector is fixed on the manganese steel sheet by using strong glue. The driving coil 55 adopts a pair of ferrite high-frequency magnetic ring coils which are symmetrically arranged on two sides of the manganese steel sheet. The control circuit 54 is composed of a timing chip, an RCL oscillation circuit, a power amplifier and an FPGA chip. The control circuit generates 1kHz oscillating current to pass through the driving coil, and the amplitude of the light spot swing can be changed by adjusting the driving current, so that the function of controlling the one-dimensional light spot track is achieved.

Example two: one-dimensional control and fixing laser welding head for light spot track

As shown in fig. 7, the bonding head in this embodiment employs a linear optical path. The collimating lens group is composed of a plano-convex lens, and the focusing lens group is composed of an aspherical aberration lens pair. The deflection assembly is formed by a pair of quartz prisms 61 that move relative to each other. The quartz prism 61 is fixed in relative position in the middle by a link 62, and the top end of the link 62 is tightened by a rubber spring 63. The rubber spring 63 is provided with a permanent magnet 64 in the middle, the driving coil 65 attracts or repels the permanent magnet 64 at the same time, and the rubber spring 63 pulls the prism to deflect to cause one-dimensional movement of the light spot track. The other devices in this embodiment are the same as those in the first embodiment.

Example three: laser welding head with deflection element for two-dimensional control of spot trajectory

As shown in FIG. 8, in the present embodiment, the collimating lens group and the focusing lens group are composed of 2 symmetric aspherical lens groups 71 and 72, and the deflecting component is composed of 2 crescent lenses 73 to form a 1:1 total astigmatic structure. The 2-month lenses 73 are respectively fixed on 2 torsion pendulums 74 made of composite elastic materials which are independent of each other. Permanent magnets are embedded in the 2 torsion pendulums 74 and are respectively driven by 2 pairs of driving coils 75 arranged in the mutually vertical directions, so that the light spot track control in one plane is realized. The 1:1 total aberration eliminating structure of the crescent lens ensures that the focusing characteristic of a light spot is unchanged during the deflection of a light spot track. The control circuit is composed of a single chip microcomputer MCU chip and peripheral devices thereof, and an oscillation circuit, a power amplification circuit and a filter circuit.

Example four: laser welding head with three-dimensional control of light spot track, multiple reflection and light splitting

As shown in fig. 9, in the present embodiment, the torsion pendulum 83 is made of a composite elastic material to form a triple suspension system, and the 45-degree mirror 85 is fixed on the third torsion pendulum. The torsion pendulum in a triple suspension system is at an angle of 120 degrees as shown in figure 4. Permanent magnets are embedded in the torsion pendulum 83, and a driving coil 84 perpendicular to the torsion pendulum 83 provides attraction force and repulsion force to drive the torsion pendulum 83 to move in three directions. The movement tracks of the laser spots in three directions are controlled by the movement of the reflecting mirror 85, so that the high-speed and high-precision control of the shape, the speed and the focusing characteristic is realized. The collimating lens assembly 82 and the focusing system lens assembly 86 are the same as in the first embodiment. The control circuit is the same as that of the embodiment.

The above description is only an embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention disclosed herein are intended to be covered by the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the appended claims.

Claims (7)

1. A spot wobble fiber laser welding head comprising:

a focusing optical system (11), the focusing optical system (11) comprising a collimating lens group (21), a deflecting assembly (22) and a focusing lens group (23);

a drive system (14), said drive system (14) being comprised of a plurality of pairs of drive coils; any one pair of the driving coils are oppositely arranged, and a magnet is arranged inside each driving coil;

the driving coil is arranged below the end part of the torsional pendulum, the magnet is coaxially arranged inside the driving coil, the driving coil and the torsional pendulum are connected through the magnet, and the magnet can move up and down along the central axis of the driving coil; the torsion pendulum (15) is fixedly connected with the deflection assembly and is used for controlling light deflection;

a control circuit (13) for controlling the drive coil;

a mechanical support structure (12) for supporting and connecting the focusing optical system (11), the control circuit (13), the drive system (14) and the torsion pendulum (15).

2. A spot swinging fiber laser welding head according to claim 1, wherein: the control circuit (13) comprises a control chip (35) and a control loop; the control loop specifically comprises a sequential circuit (31), an oscillating circuit (32), a delay circuit (33) and an operational amplifier circuit (34).

3. A spot swinging fiber laser welding head according to claim 1, wherein: the deflection assembly comprises in particular a mirror, a refractive prism or a grating.

4. A spot swinging fiber laser welding head according to claim 1, wherein: the torsion pendulum (15) is characterized in that a plurality of torsion springs are overlapped and staggered, and a first fixing point (451), a second fixing point (452) and a third fixing point (453) of the torsion springs are positioned in the same direction of the driving coil.

5. A spot swing fiber laser welding head according to claim 4 wherein: the torsion spring is made of a spring steel sheet, a spring steel wire, a rubber spring or an elastic composite material.

6. A spot swinging fiber laser welding head according to claim 1, wherein: the collimating lens group is specifically a plano-convex lens or an aplanatic lens group.

7. A spot swinging fiber laser welding head according to claim 1, wherein: the focusing lens group is specifically a plano-convex lens or an aplanatic lens group.

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