LASER CLADDING METHOD AND DEVICE FOR IMPLEMENTING SAME

Abstract

A method and device for laser cladding by independently heating the cladding material and the surface of the workpiece consist in formation of the series of parallel annular laser beams, possibly different wavelengths, with an adjustable distribution of laser radiation power across the annular beams. The annular beams are transformed into a series of conical beams which are separately focused along a single optical axis, along which the cladding material is fed. The device can be supplemented with a cylindrical mirror for the multipass laser radiation through the stream of cladding material with the possibility of the laser radiation return to the laser resonator.

Claims

1.-3. (canceled)

4. A laser cladding method, comprising: feeding a cladding material into a focal region of a laser beam, which being located on a surface of an object to be treated, wherein: a series of parallel annular laser beams is formed from an initial circular laser beam with an adjustable distribution of laser radiation power across the annular beams; the annular beams are transformed into a series of conical beams and are separately focused along a single optical axis, along which the cladding material is fed.

5. The method according to claim 4, wherein the cladding material is a solid, a liquid, a gas, a powder, an aerosol or a heterogeneous plasma.

6. The method according to claim 4, wherein laser radiation wavelengths are different for different annular beams.

7. A laser cladding device, comprising: a laser, which is optically linked to a first system for forming a conical beam, a focusing lens and system for feeding a cladding material; wherein the device is supplemented with an optical system for forming a series of annular laser beams with an adjustable distribution of laser radiation power across the annular beams, a rotating mirror with an opening through which tubes are passed for feeding a gas, a cooling liquid and the cladding material, and a system of conical focusing mirrors; a lens focus and conical mirrors focuses are located along a single optical axis along which the cladding material is fed.

8. The device according claim 7, wherein the device is supplemented with a cylindrical mirror for a laser radiation mulipassage through a stream of the cladding material with a possibility of a laser radiation return to a laser resonator.

9. A laser cladding device, comprising: a laser, which is optically linked to a first system for forming a conical beam, a focusing lens and system for feeding a cladding material; wherein the device is supplemented with an optical system for converting a laser wavelength, an optical system for forming a series of annular laser beams of different wavelengths with an adjustable distribution of a laser radiation power across the annular beams, a rotating mirror with dichroic areas and with an opening through which tubes for feeding a gas, a cooling liquid and the cladding material are passed, and a system of conical focusing mirrors; and a lens focus and conical mirrors focuses are located along a single optical axis along which the cladding material is fed.

Description

BRIEF DESCRIPTION OF FIGURES

[0023] FIG. 1 is the variant of an optical scheme of the inventive device.

[0024] FIG. 2 is the variant of an optical scheme of the production a series of parallel annular laser beams with an adjustable distribution of laser radiation power across the annular beams.

[0025] FIG. 3 is another variant of an optical scheme of the production a series of parallel annular laser beams with an adjustable distribution of laser radiation power across the annular beams.

[0026] FIG. 4 is the variant of an optical scheme of the inventive device with reflective optics and system of laser beams control.

[0027] FIG. 5 is the variant of an optical scheme of the inventive device with annular beams having different wavelengths.

[0028] FIG. 6 is the variant of a multipass optical scheme.

DETAILED DESCRIPTION OF THE INVENTION

[0029] The objective of the claimed invention is to elaborate a method and apparatus for laser cladding that ensures improvement of the laser processing method, increase of productivity, reduce of energy consumption while ensuring high precision in the manufacture of parts.

[0030] The claimed method of laser cladding consists in applying the deposited material in the focal region of the laser beam which is placed on the surface of the workpiece. Unlike other methods from the initial laser beam a series of circular annular laser beams are formed with an adjustable power distribution across the annular beams. The annular beams are transformed into a series of conical laser beams using conical lens and conical mirrors

[0031] Conical beams are separately focused as to the surface of the workpiece to heat it, and to various areas of the optical axis along which the cladding material is fed. A stream of gas, liquid, powder, heterogeneous plasma jet or wire can be used as cladding material.

[0032] Focused conical beams heat various regions of the stream of cladding material. Space-independent and separated heating of workpiece and stream of cladding material provides optimum thermal process conditions, can significantly reduce energy costs and increase cladding accuracy.

[0033] For more efficient heating a workpiece and a cladding material with different spectral absorptivity a wavelengths of the laser radiation may be different for annular beams.

[0034] With the aim of realization of the claimed method, new device for laser cladding is elaborated, comprising a laser optically coupled with the system of forming a series of conical beams for separate heating of the workpiece and the stream of cladding material.

[0035] New is that the device is further provided with a system of forming a series of parallel annular laser beams with adjustable laser power distribution across the annular beams, deflecting mirror with an opening for wiring the gas supply tubes, coolant and the cladding material, focusing lens and conical mirrors. The focus of the lens and the foci of conical mirrors lie on the same optical axis along which the cladding material is fed to the surface.

[0036] The device (FIG. 1) comprises a laser 1 optically coupled with an optical system forming a series of annular laser beam with an adjustable power distribution across laser beams which comprises adjustable beam expander 2, and multifacet reflective waxicon 3. Series of parallel annular beams are deflected by mirror 4 with an opening for wiring tubes with the coolant 6, the feed gas and the cladding material 5.

[0037] Additionally the device includes a focusing lens 7, the focusing conical mirrors 8.9. One annular beam is focused by lens 7 into the surface of the workpiece 11 and others annular beams are focused by conical mirrors 8,9 into various regions 13, 14 of the cladding material stream 10.

[0038] The device operates as follows. The laser beam 1 after passing through the beam expander 2 and multifacet waxicon 3 is transformed into a series of annular beams. One of the beams is focused by lens 7 on the product surface 11 to a spot irradiation 12 and melt surface in spot. Cladding material is fed through the tube 5 in the form of a powder stream 10, liquid, plasma or heterogeneous gas stream or wire. Other beams are focused by means of conical mirrors 8, 9 in the predetermined region 13, 14 of the stream 10 to heat these regions 13,14.

[0039] By changing the dimensions of the beam 15 after the beam expander 2 can redistribute the power of the laser on areas 12, 13 and 14 and thereby regulate the process of cladding and efficiency of the heating the surface and a stream of material. This reduces the size of the molten bath, increases the energy input into the solid wire or stream of cladding material because of their small heat sink and, if stream, because of the large absorption of the laser radiation in dense stream.

[0040] New systems for annular beams production were elaborated (FIG. 2, 3).

[0041] The systems further comprises a multiaxicons, multifacet mirror or multifacet lens adjustable beam expander and generator of radiation intensity distribution over the cross section of the laser beam source.

[0042] The devices operate as follows. Radiation of laser 1 with a Gaussian intensity distribution over the cross section of the beam 42 is translated using generator 40 into a predetermined 44 distribution—rectangular or any other (super-Gaussian, Lager-Gaussa etc.), followed by an adjustable beam expander 2 which increases beam 15 to a predetermined size. The beam 15 is converted by negative 41 or reflective multiaxicon 47 in a series of divergent beams, which are converted into a series of parallel annular beams 21 22 using multifacet lens 42 or multifacet conical mirror 3. Changing the size of the circular beam 15 and the intensity distribution over the cross section of the beam the distribution of laser power between 21 and 22 annular beams is changed.

[0043] Variant of the claimed device with conical reflective optics, which is important when using high-power lasers, is shown in FIG. 4. Instead of the lens 7 (FIG. 1) is set focusing conical mirror 23. In this scheme also introduced the option of using part of the laser radiation, shaded by tube 5. This radiation can be used for heating tube 5 and cladding material passing through it. In other embodiment of the device (FIG. 4), this part of the radiation is deflected by mirror 24 to block of the laser parameters control 25.

[0044] For more efficient heating a workpiece and a cladding material with different spectral absorptivity device is supplemented with an optical system for converting the laser wavelength, an optical system for forming a series of annular laser beams of different wavelengths with an adjustable distribution of laser radiation power across the annular beams, a rotating mirror with the dichroic areas.

[0045] The ring beam 33 with λ1 wavelength (FIG. 5) of radiation is converted using converter 26 to ring beam 34 with wavelength Δ2. With the use of rotary mirrors 27, 30 refractive axicon 32 and waxicon 31 conical mirrors 29 and 28 annular laser beams with different wavelengths are formed. These beams are deflected by dichroic mirrors 46 and 35 to the lens 7 and the conical mirror 8. As a result, the heating of the workpiece 11 in the focus of the lens 7 and the stream 10 of the cladding material is carried out by laser radiation with different wavelength.

[0046] At low absorption of laser radiation in the stream of the cladding material drops sharply efficiency of laser radiation use when a single pass through stream. For maximum use of radiation offered multipass scheme using a cylindrical mirror 36, 37 (FIG. 6). It first increases the stream heating and secondly allows efficiently use of the laser radiation up to the full absorption when returning the coherent part of the laser radiation to laser resonator.

[0047] Thus, the claimed method and apparatus of laser cladding, reduces energy consumption, improve the accuracy and quality of cladding.