Laser device for additive manufacturing and operation method thereof

Abstract

A laser device for additive manufacturing and an operation method thereof are provided. The laser device has a laser generation unit, a spectroscopic unit, a control unit, and a lens assembly unit. A laser beam is split into two or more beams by disposing the spectroscopic unit and the lens assembly unit. Thus, a roughness of a process surface and a process time can be reduced.

Claims

1. A laser device for additive manufacturing, comprising: a laser generation unit configured to emit a laser beam; a spectroscope unit configured to receive the laser beam and split the laser beam into separate beams, wherein the spectroscope unit comprises a spot modulation lens assembly, a laser spectroscope, and a rotary component, wherein the spot modulation lens assembly is disposed at a light downstream side of the laser generation unit and configured to receive the laser beam and modulate a size of a spot of the laser beam, the laser spectroscope is disposed at a light downstream side of the spot modulation lens assembly and configured to receive the laser beam modulated by the spot modulation lens assembly and split the laser beam into the separate beams, the laser spectroscope is disposed in the rotary component, and the rotary component is configured to move or rotate the laser spectroscope along an optical axis direction of the laser beam modulated by the spot modulation lens assembly; a control unit electrically connected to the spectroscope unit; and a lens assembly unit configured to receive the separate beams and reflect the separate beams to a working platform; wherein the rotary component includes a shell, a stator, and a plurality of air inlets, wherein the stator is disposed inside the shell, the air inlets are formed in the shell, and the laser spectroscope is located inside the rotary component and configured to be a rotor.

2. The laser device according to claim 1, wherein the spectroscope unit further comprises a space adjustment lens assembly, and the space adjustment lens assembly is disposed at a light downstream side of the laser spectroscope and configured to receive the separate beams split by the laser spectroscope and adjust a degree of divergence of the separate beams.

3. The laser device according to claim 1, wherein the lens assembly unit comprises a scanning galvanometer, and the scanning galvanometer is disposed at a light downstream side of the space adjustment lens assembly and configured to receive the separate beams adjusted by the space adjustment lens assembly, so that the separate beams are reflected to the working platform along a direction after being reflected from the scanning galvanometer.

4. The laser device according to claim 3, wherein the lens assembly unit further comprises a focusing lens assembly, and the focusing lens assembly is disposed at a light output side of the scanning galvanometer and configured to focus the separate beams reflected by the scanning galvanometer on a plane.

5. The laser device according to claim 1, wherein the laser device is disposed in an optical system of a powder bed melt molding device.

6. An operation method of a laser device for additive manufacturing according to claim 1, comprising: a preparation step of generating a laser beam using a laser generation unit; a splitting step of splitting the laser beam into separate beams using a spectroscope unit; and a reflecting step of reflecting the separate beams to a working platform using a lens assembly unit.

7. The operation method according to claim 6, wherein in the splitting step, a laser spectroscope of the spectroscope unit is driven to move or rotate along an optical axis direction of the laser beam.

Description

DESCRIPTION OF DRAWINGS

(1) FIG. 1 is a schematic view of a laser device for additive manufacturing according to the preferred embodiment of the present disclosure.

(2) FIG. 2 is a schematic view of a rotary component of the laser device for additive manufacturing according to the preferred embodiment of the present disclosure.

(3) FIGS. 3a and 3b are schematic views of separate beams reflected to a working platform of the laser device for additive manufacturing according to the preferred embodiment of the present disclosure.

(4) FIGS. 4a and 4b are patterns actually displayed with separate beams reflected to a working platform of the laser device for additive manufacturing according to the preferred embodiment of the present disclosure.

(5) FIG. 5 is a pattern actually displayed with a single laser scanning trajectory of the laser device for additive manufacturing according to the preferred embodiment of the present disclosure.

(6) FIG. 6 is a pattern actually displayed with a two-zone laser scanning trajectory of the laser device for additive manufacturing according to the preferred embodiment of the present disclosure.

(7) FIG. 7 is a flowchart of an operation method of the laser device for additive manufacturing according to a preferred embodiment of the present disclosure.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

(8) The structure and the technical means adopted by the present disclosure to achieve the above and other objects can be best understood by referring to the following detailed description of the preferred embodiments and the accompanying drawings. Furthermore, directional terms described by the present disclosure, such as upper, lower, front, back, left, right, inner, outer, side, longitudinal/vertical, transverse/horizontal, etc., are only directions by referring to the accompanying drawings, and thus the used directional terms are used to describe and understand the present disclosure, but the present disclosure is not limited thereto.

(9) Referring to FIG. 1, a schematic view of a laser device for additive manufacturing according to the preferred embodiment of the present disclosure is provided, wherein the laser device is disposed in a light path system of a powder bed melt molding device (not shown), and the laser device comprises a laser generation unit 2, a spectroscope unit 3, a control unit 4, and a lens assembly unit 5. The detailed structure of each component, assembly relationships, and principles of operation for the present invention will be described in detail hereinafter.

(10) Referring to FIG. 1, the laser generation unit 2 is configured to emit a laser beam 101, wherein the laser generation unit 2 has a laser generator 21 and a collimator 22. The laser generator 21 is provided for generating the laser beam 101 emitted toward the collimator 22. The collimator 22 is configured to assist a traveling direction of the laser beam 101 in being substantially parallel to a straight light (also known as collimated light or parallel light).

(11) Referring to FIGS. 1 and 2, the spectroscope unit 3 is configured to receive the laser beam 101 and split the laser beam 101 into separate beams 102, and the spectroscope unit 3 has a spot modulation lens assembly 31, a laser spectroscope 32, a rotary component 33, and a space adjustment lens assembly 34.

(12) Furthermore, the spot modulation lens assembly 31 is disposed at a light downstream side of the laser generation unit 2 and configured to receive the laser beam 101 and modulate a size of a spot of the laser beam 101. The laser spectroscope 32 is disposed at a light downstream side of the spot modulation lens assembly 31 and configured to receive the laser beam 101 modulated by the spot modulation lens assembly 31 and split the laser beam 101 into the separate beams 102. In the preferred embodiment, the laser spectroscope 32 is a diffraction optical element (DOE) for forming multiple beams by splitting. The number of the separate beams 102 split from the laser beam 101 is three, and the number of the separate beams 102 can be adjusted according to demand. For example, the number of the separate beams 102 is an odd number, such as the number 3, 5, 7, or 9.

(13) Referring to FIGS. 1 and 2, the laser spectroscope 32 is disposed in the rotary component 33, and the rotary component 33 is configured to move or rotate the laser spectroscope 32 along an optical axis direction of the laser beam 101 modulated by the spot modulation lens assembly 31. In the preferred embodiment, the rotary component 33 can be a rotary hollow motor, an air bearing, or a magnetic bearing. The rotary component 33 is an air bearing shown in FIG. 2. Specifically, the rotary component 33 has a shell 331, a stator 332, and a plurality of air inlets 333, wherein the stator 332 is disposed inside the shell 331, the air inlets 333 are formed in the shell 331, and the laser spectroscope 32 is located inside the rotary component 33 and is a rotor. The rotary component 33 drives a position control of rotary speed and linear location of the rotary component 33 by a rotary driving and linear driving motor and a controller linked to the control unit 4 (such as computer), wherein the laser spectroscope 32 (shown in FIG. 2) can be installed within the rotary component 33 to form a rotary mechanism with a rotary shaft. Thus, the laser spectroscope 32 rotates beams with respect to the rotary component 33.

(14) Referring to FIGS. 1 and 2, the space adjustment lens assembly 34 is disposed at a light downstream side of the laser spectroscope 32 and configured to receive the separate beams 102 split by the laser spectroscope 32 and adjust a degree of divergence of the separate beams 102.

(15) Referring to FIGS. 1 and 2, the control unit 4 is connected to the spot modulation lens assembly 31, the rotary component 33 and the space adjustment lens assembly 34 of the spectroscope unit 3, wherein the control unit 4 can control the spot modulation lens assembly 31 to modulate the size of the spot of the laser beam 101. In the preferred embodiment, the spot modulation lens assembly 31 changes a focus position of the spot according to a length of a light path and modulates the size of the spot according to the optical axis direction. In addition, the control unit 4 also controls the rotary component 33 to move along the optical axis direction of the laser beam 101 or rotate along the optical axis being a central axis. For example, the position control of rotary speed and linear location of the rotary component 33 are driven by the rotary driving and linear driving motor and the controller, or a forward rotation and a reverse rotation of the rotary component 33 are driven along the optical axis being the central axis. The control unit 4 further controls the space adjustment lens assembly 34 to adjust the degree of divergence of the separate beams 102.

(16) Referring to FIGS. 1 and 2, the lens assembly unit 5 is configured to receive the separate beams 102 and reflect the separate beams 102 to a working platform 103, wherein the lens assembly unit 5 comprises a scanning galvanometer 51 and a focusing lens assembly 52. The scanning galvanometer 51 is disposed at a light downstream side of the space adjustment lens assembly 34 and configured to receive the separate beams 102 adjusted by the space adjustment lens assembly 34, so that the separate beams 102 are reflected to the working platform 103 along a direction after being reflected from the scanning galvanometer 51. The focusing lens assembly 52 is disposed at a light output side of the scanning galvanometer 51 and configured to focus the separate beams 102 reflected by the scanning galvanometer 51 on a plane.

(17) Referring to FIGS. 1, 3a and 3b, the separate beams 102 split from the laser spectroscope 32 are transmitted to the working platform 103 through the space adjustment lens assembly 34, the scanning galvanometer 51, and the focusing lens assembly 52, wherein an axis of a spot of a second beam 102 is a rotary axis X, and a spot of a first beam and a spot of a third beam can be processed for the position control of rotary speed and linear location according to the rotary axis X being a central axis by driving the rotary component 33. Thus, a space and an arrangement direction of the separate beams 102 are adjusted. For example, large spaces are shown in FIG. 3a, wherein a space W1 is formed between the first beam 102 and the second beam 102, and a space W2 is formed between the second beam 102 and the third beam 102. A pattern actually displayed with the separate beams is shown in FIG. 4a. Narrow spaces are shown in FIG. 3b, wherein a space D1 is formed between the first beam 102 and the second beam 102, and a space D2 is formed between the second beam 102 and the third beam 102. A pattern actually displayed with the separate beams is shown in FIG. 4b. In addition, FIG. 5 shows a single laser scanning trajectory (as shown by solid lines), and the single laser scanning trajectory can scan with three beams at the same time. Compared with a single beam in the prior art, the laser scanning time can be saved by 83%. FIG. 6 further shows a two-zone laser scanning trajectory (as shown by solid and dashed lines). Compared with the single beam in the prior art, the laser scanning time can be saved by 66%, and the laser scanning trajectory is flatter.

(18) According to the described structure, the size of the spot of the laser beam 101 is adjusted by the spot modulation lens assembly 31 after the laser beam 101 is emitted from the collimator 22. Then the laser beam 101 is split into the separate beams 102 by the laser spectroscope 32, and the degree of divergence of the separate beams 102 caused by splitting are adjusted by the space adjustment lens assembly 34. After that, movement of the rotary component 33 is controlled by the control unit 4, so that the rotary component 33 are moved along the optical axis direction or rotated along the optical axis being the central axis. Thus, the space and the arrangement direction of the separate beams 102 are adjusted. Finally, the separate beams 102 are reflected to the working platform 103 by the scanning galvanometer 51, and the focusing lens assembly 52 is adopted to assist the scanning galvanometer 51 and focus the separate beams 102 on the same plane to process a laser operation.

(19) As described above, the laser device for additive manufacturing is designed with the spectroscope unit 3 and the lens assembly unit 5 to split the laser beam 101 into the separate beams 102 and to focus the separate beams on the working platform 103, wherein the space and the arrangement direction of the spot (focus point) of the separate beams 102 are controlled according to the demand of the process and scanning strategy to achieve that a single galvanometer can adjust the laser process with multiple beams. It can reduce surface roughness of said process and decrease the process time. Thus, the purpose of optimizing the process speed and accuracy can be achieved.

(20) Referring to FIG. 7 in conjunction with FIG. 1, an operation method of a laser device for additive manufacturing is provided and operated by said laser device for additive manufacturing, wherein the operation method comprises a preparation step S201, a splitting step S202, and a reflecting step S203.

(21) Referring to FIG. 7 in conjunction with FIG. 1, in the preparation step S201, a laser beam 101 is generated by using a laser generation unit 2. In the preferred embodiment, the laser beam 101 is generated by a laser generator 21, and emitted by the collimator 22, and a traveling direction of the laser beam 101 assisted to be substantially parallel to a straight light by the collimator 22.

(22) Referring to FIG. 7 in conjunction with FIG. 1, in the splitting step S202, the laser beam 101 is split into separate beams 102 by a spectroscope unit 3, and a laser spectroscope 32 of the spectroscope unit 3 is driven to move along an optical axis direction of the laser beam 101 and to rotate along the optical axis being the central axis. Thus, a space and an arrangement direction of the separate beams 102 are adjusted.

(23) Referring to FIG. 7 in conjunction with FIG. 1, in the reflecting step S203, the separate beams 102 are reflected to a working platform 103 by a lens assembly unit 5. In the preferred embodiment, the separate beams 102 are reflected to the working platform 103 by the scanning galvanometer 51, and the focusing lens assembly 52 is adopted to assist the scanning galvanometer 51 and focus the separate beams 102 on the same plane to process a laser operation.

(24) As described above, according to the operation method of a laser device for additive manufacturing the present disclosure, the laser beam 101 is split into the separate beams 102 and the separate beams are focused on the working platform 103, wherein the space and the arrangement direction of the spot (focus point) of the separate beams 102 are controlled according to the demand of the process and scanning strategy to achieve that a single galvanometer can adjust the laser process with multiple beams. It can reduce surface roughness of said process and decrease the process time. Thus, the purpose of optimizing the process speed and accuracy can be achieved.

(25) The present disclosure has been described with preferred embodiments thereof and it is understood that many changes and modifications to the described embodiments can be carried out without departing from the scope and the spirit of the invention that is intended to be limited only by the appended claims.