JP2000233287A - Melting working device using laser beam and arc - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve melting working and welding efficiency by using effectively both of laser beam energy and discharge arc energy at the same time, and to improve the miniaturization and the portability of a melting working device. SOLUTION: This melting working device is equipped with a laser beam system converging the laser beam of a laser beam source 20 on a work after choking it through optical systems 120, 130 and irradiating the work with it and a nozzle electrode 150 arranged in a position opposed to the work in almost the same axial relation to the optical axis of the laser beam system and to which a high voltage for an arc discharge is supplied. Melting and working are performed by the arc discharge while the work is melted by the irradiation by the laser beam.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fusion processing apparatus and a fusion processing method using a laser beam and an arc, and more particularly, to improve the fusion processing and connection efficiency by effectively using both laser beam energy and discharge arc energy. And a melting method using a laser beam and an arc.

[0002]

2. Description of the Related Art Thermal processing by arc discharge has been widely used for processing metals and the like. On the other hand, the laser processing technology of processing by irradiating a laser beam having high-density thermal energy to a very small beam diameter and irradiating and melting a workpiece which is a workpiece or a workpiece, has a high efficiency, high precision, Attention has been paid to low thermal strain characteristics.

[0003]

However, despite the laser processing method having such usefulness, problems still remain. For example, for high-power laser light emission, a high-output laser light emission source is required, and the power supply for light emission also becomes complicated in structure and large in size due to poor conversion efficiency from power. It limits the expansion of its application range. Thus, despite the benefits described above, laser welding is limited in its application to the processing of sheet layers as compared to other gas, electric, arc, etc. welding processes. In particular, the application of laser welding is
In many fields, joint accuracy is required, and high output is required to increase the processing speed, and equipment costs are also high.

[0004] Further, due to the above-mentioned problems, the size of the melt processing apparatus itself becomes large, and it is expensive and portable.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a melt processing apparatus and a melt processing method using a laser beam and an arc, in which both the laser beam energy and the discharge arc energy are effectively used in combination, and the connection efficiency is improved. To provide.

Another object of the present invention is to provide a melt processing apparatus and a melt processing method using a laser beam and an arc which are small in size and excellent in portability.

[0007]

In order to solve the above-mentioned problems, a melt processing apparatus and a melt processing method using a laser beam and an arc according to the present invention employ the following characteristic configurations.

(1) A laser light system for focusing and irradiating a laser beam from a laser light source via an optical system on a work and facing the work in a substantially coaxial positional relationship with the optical axis of the laser light system. A nozzle electrode provided with a nozzle electrode to which a high voltage for arc discharge is supplied, and a laser beam for melting and processing by the arc discharge in a state where the work is melted by the irradiation of the laser beam. Melt processing equipment using arc.

(2) An outer cylinder and an inner cylinder substantially coaxial with the outer cylinder. The laser beam from the laser light source is narrowed down inside the inner cylinder to collect and irradiate the laser beam from the opening onto the work. An inverted conical nozzle electrode to which a high voltage for arc discharge is supplied is provided outside the laser light path near the opening, and the work is irradiated with the laser light. A melting processing apparatus using a laser beam and an arc, wherein melting and processing by the arc discharge are performed in a molten state.

(3) The laser beam and the arc of (1) or (2), wherein an inert gas is introduced substantially coaxially with the laser beam system and is ejected from the opening onto the melted work surface. Melt processing equipment.

(4) The laser beam and the arc of (1), (2) or (3), which cause an inert gas to flow in a direction substantially coaxial with the laser beam system and eject it to the nozzle electrode and the work surface. Melt processing equipment.

(5) The melt processing apparatus according to the above (3), wherein the inert gas is an argon gas and the laser beam and the arc are used. ,

(6) The melt processing apparatus according to (4), wherein the inert gas is a mixed gas of an argon gas and a hydrogen gas, using the laser beam and the arc. ,

(7) The work side of the nozzle electrode is
The melt processing apparatus using the laser light and the arc according to the above (1) or (2), which is made of a tungsten material.

(8) The light source of the laser beam is a YAG laser or a carbon dioxide laser as described in (1) or (2) above.
Processing equipment using laser light and arc.

(9) A high voltage for arc discharge is supplied in a position substantially coaxial with the optical axis of the laser light system for focusing and irradiating the laser light from the laser light source via the optical system to converge and irradiate the laser light on the work. A melting process using a laser beam and an arc for performing melting and processing by the arc discharge in a state where the nozzle electrode is opposed to the work and the work is melted by the irradiation of the laser beam.

(10) The melting process using the laser beam and the arc according to the above (9), wherein an inert gas is jetted to the melted work surface and the nozzle electrode.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of a melt processing apparatus and a melt processing method using a laser beam and an arc according to the present invention will be described below in detail with reference to the accompanying drawings. FIG.
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a configuration diagram of a partial cross section showing one embodiment of a melting processing apparatus and a melting processing method using a laser beam and an arc according to the present invention. FIG. 2 is a simplified cross-sectional view of the melt processing unit (torch part) 10 of FIG.

The laser light oscillated from the YAG laser 20 as a laser oscillation source passes through an optical fiber 21 and enters a laser light guide section of a melting unit (torch section) 10 described later. In addition, a center gas composed of an inert gas (for example, argon gas Ar) from the gas cylinder 40 is introduced into the opening 111 of the melt processing unit 10 through the gas valve 41 and the center gas hose 42. Similarly, a shielding gas (for example, argon gas Ar + hydrogen H2 as an inert gas) from the gas cylinder 50 is introduced into the opening 121 of the melt processing unit 10 through the gas valve 51 and the center gas hose 52.

As shown in FIG. 2, the melt processing unit 1
Reference numeral 0 denotes an outer cylinder 100 made of an electrically insulating material, and an inner cylinder 110 substantially coaxial with the outer cylinder 100, and guides a laser beam to a work W (see FIG. 1) as a workpiece (workpiece). A laser light guide section for focusing, and an arc processing section for melting and processing a workpiece by an arc are provided. The tip of the optical fiber 21 is inserted into the opening 101 of the top 102 at the top of the outer cylinder 100. The laser light emitted from this tip portion is collimated by a lens 120 and a focusing lens 13.
The beam is narrowed down to an extremely small beam by an optical system composed of 0 and the like, and is focused near the workpiece W. These optical systems can be attached to the inner wall of the inner cylinder 110.

At the lower end of the outer cylinder 100, a shield cup 160 made of a heat-resistant material having a small diameter at the tip end (narrowed down) and having an inverted conical cross section is screwed and fixed with a screw portion 160A. The reason for fixing with screws is that the substantially inverted conical shield cup 160 made of a heat-resistant material (for example, a ceramic material) is exposed to high heat, so that it is consumed more heavily than other parts, thereby facilitating replacement.

A nozzle electrode 150 for arc discharge having a substantially inverted conical shape similar to the shield cup 160 is fixed to the inner surface side of the shield cup 160 substantially in parallel by screwing or the like. The reason for fixing by screwing is that, similarly to the shield cup 160, it is exposed to high heat so that it is consumed more intensely than other parts, and replacement is easy. The nozzle electrode 150 is made of a copper material, and the tip portion is made of a metal such as a tungsten material having a high melting point in order to avoid damage caused by high heat due to the generated arc.

An opening 111 is formed in the outer cylinder 100 at a position slightly lower than the fixed mounting position F of the inner cylinder 110, and the center gas is supplied to the gas valve 41 and the gas hose 42 in the opening 111 as described above. Inflows through. The inflow center gas is supplied to the outer cylinder 100 and the inner cylinder 110
Through the gas guide passage 180 which is a space formed by the above, the gas flows out from the opening P1 through the inner surface side of the nozzle electrode 150 as shown by the solid line arrow in the drawing, and is ejected to the work W.

An opening 121 is provided below the outer cylinder 100.
The shield gas flows in from the opening 121 via the gas valve 51 and the gas hose 52, and passes through the gas guide passage 170 which is a space between the shield cup 160 and the nozzle electrode 150, as shown by a one-dot chain line arrow in the drawing. Flows out of the opening P2.

The constant current DC power supply 30 is a power supply for DC welding with constant current characteristics.
The + electrode is connected to the work W, and the work W is processed.

The embodiment of the present invention has the above-described basic configuration, and the processing operation is as follows.

The outer cylinder 100 of the melt processing unit 10 is held by an appropriate holder (a drive device for controlling movement and the like), and the work W and the opening P1 (nozzle electrode portion) at the tip end of the melt processing unit 10 are connected. The workpiece W is arranged so as to have a predetermined positional relationship, that is, the work W is located at the in-focus position of the laser beam at the lower end of the melt processing unit 10. Here, if the operator holds the melt processing unit 10 by hand, the portability is expanded, so that it is of course effective.

Next, the gases from the gas cylinders 40 and 50 are introduced into the openings 111 and 121 of the melt processing unit 10 by opening the gas valves 41 and 51 as appropriate.
Subsequently, a laser power supply for driving a YAG laser (laser oscillator) 20 and a constant current DC power supply 30 as a welding power supply are turned on, and a DC voltage is applied between the electrode and the work W to the work W, which is a workpiece, to melt the work. Set to the standby state.

Referring to the schematic diagram of FIG. 3, the laser light emitted from the distal end of the optical fiber 21 through the opening 101 of the melting processing unit 10 is, as described above, an optical system including the lenses 120 and 130 and the opening. The light is condensed through P1 and irradiates the work W disposed at the in-focus position. Thus, the work W is instantaneously melted by the laser energy, and the melted work metal is vaporized into metal and turned into plasma. The plasma gas is applied to the nozzle electrode 150.
, An arc is generated from the tip of the nozzle electrode 150 by the DC voltage already applied. As is clear from the well-known arc theory, the positive pole of this arc is guided to the highest temperature portion (the portion that is melted by the laser beam) on the workpiece W and is reliably positioned, and the arc is located on the circumference of the electrode tip. Arising from one point.

Therefore, in the present invention, both the energy of the laser energy and the energy of the arc are concentrated at one point of the work, a further high temperature state is obtained, and the processing becomes reliable and easy.

Further, it has been experimentally confirmed that the absorption rate of the laser beam energy of the work metal increases as the melting temperature increases. Therefore, according to the present invention, a synergistic effect is obtained, and the welding point is extremely large. It will be melted quickly, and the welding speed can be increased.

Next, the utility of the center gas and the shielding gas in this embodiment will be described. First, the center gas introduced from the opening 111 of the melt processing unit 10 passes through the gas guide passage 180 and passes through the nozzle electrode 15.
It is ejected toward the workpiece W from the opening P1 having a small diameter at the leading end. Here, as schematically shown in FIG.
Is melted at an extremely high temperature, and a metal vapor is generated at the center thereof, thereby causing dents and holes. Therefore, the ejection of the center gas enhances heat conduction to the lower portion of the work W and is effective for melting. In general, in the work welding of a thick plate, a method in which a hole penetrating from the top to the bottom is formed and welding is performed while melting the periphery thereof (keyhole welding). In such a method, it is clear that the center gas ejected from the tip of the steam nozzle is effective in forming the dents and holes.

Further, by controlling the ejection of the center gas to the work W, it is possible to change the shape of the melting point and obtain the required penetration. For example, when the center gas jet is weak as shown in FIG. 4 (A), the depth of the pits and holes formed is shallow, but as shown in FIG. 4 (B), when the center gas jet is strong, The depth of the formed dent or hole is increased.

Further, the opening 121 of the melt processing unit 10
Gas introduced from the gas guide passage 170
Through the opening P2 of the minute gap. here,
Since the discharge nozzle electrode 150 and the work metal have a high temperature such as the melting temperature, they may be oxidized or nitrided by oxygen or nitrogen in the air, and may cause deterioration of the material. But,
In this embodiment, since the shield gas, which is a mixed gas of the Ar gas and the H2 gas, is jetted to the nozzle electrode 150 and the work metal, the oxidation and the nitridation can be prevented. Further, a thermal pinch effect can be obtained by the shield gas. That is, of the mixed gas of the Ar gas and the H2 gas, the H2 gas has a cooling effect, the cross-sectional area of the arc column generated by the discharge is contracted and becomes rigid, the energy density is further increased, and the welding efficiency is increased. Is significantly improved.

In the above-described embodiment, a YAG laser is used as a laser. However, other lasers can be used as long as they are high power lasers. For example, a carbon dioxide laser or a semiconductor laser can be used. Further, as the inert gas, other appropriate inert gas such as helium gas can be used.

Although the preferred embodiment of the melt processing apparatus and method using laser light and arc of the present invention has been described above, this is only an exemplification, and various modifications may be made in accordance with a specific application. Of course, it is possible.

[0037]

As described above, the melting apparatus and the melting method using the laser beam and the arc according to the present invention effectively use both the laser beam energy and the discharge arc energy. Processing efficiency is significantly improved.

Further, the laser beam emitting direction and the arc discharge direction are set to be the same direction, and the melting processing unit 10 is constituted by a coaxial outer cylinder and an inner cylinder. The laser beam is guided into the inner cylinder to irradiate the workpiece. In addition, since the nozzle electrode for discharge is provided at the lower end inside the inner cylinder with an open end, the optical system for guiding the laser beam and the nozzle electrode can be installed inside the same cylinder, which can reduce the size. Very effective.

Further, the dent and hole control of the work can be effectively performed by the ejection of the center gas which is ejected toward the work from the small-diameter opening at the tip of the nozzle electrode, and the necessary melting is obtained by changing the shape of the melting point. Not only can the nozzle electrode and the work metal be prevented from being oxidized or nitrided by the shielding gas ejected from the opening that is the exit of the minute gap through the passage between the nozzle electrode and the outer cylinder (shield cup), and the thermal pinch can be prevented. The effect can significantly improve the welding efficiency.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of an embodiment of a melt processing apparatus using a laser beam and an arc according to the present invention.

FIG. 2 is a simplified sectional view of the melt processing unit 10 shown in FIG.

FIG. 3 is a schematic diagram for explaining the operation of a melting apparatus using laser light and an arc according to the present invention.

FIG. 4 is a schematic diagram for explaining the operation of a melting apparatus using laser light and an arc according to the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Melting unit (torch part) 20 YAG laser 21 Optical fiber 40, 50 Gas cylinder 41, 51 Gas valve 42, 52 Gas hose 100 Outer cylinder 110 Inner cylinder 101 Opening 102 Top 111, 121 Opening 120 Collimating lens 130 Condensing Lens 150 Nozzle electrode 160 Shield cup

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[Procedure amendment]

[Submission date] February 17, 2000 (2000.2.1
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[Title of the Invention] Melt processing device using laser light and arc

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[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a melting apparatus using a laser beam and an arc, and more particularly, to a laser processing apparatus using a laser beam energy and a discharge arc energy in an effective combination to improve a melting process and a connection efficiency. The present invention relates to a melt processing device using an arc.

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Accordingly, an object of the present invention is to provide a melt processing apparatus using a laser beam and an arc, in which both the laser energy and the discharge arc energy are effectively used in combination to improve the melt processing and the connection efficiency. is there.

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It is another object of the present invention to provide a melt processing apparatus using a laser beam and an arc which is small in size and excellent in portability.

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[0007]

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems, a melt processing apparatus using a laser beam and an arc according to the present invention employs the following characteristic configuration.

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(1) An outer cylinder, a main body composed of an inner cylinder substantially coaxial with the outer cylinder, and one end of the main body covered with the one end, and an optical fiber for guiding laser light is fixed. A top having an opening, and an optical system provided inside the inner cylinder, for converging and irradiating a laser beam from the optical fiber onto a work through an opening provided at the other end of the main body. And a nozzle electrode having an inverted conical shape in the inner space provided near the opening on the other end side of the main body and supplied with a high voltage for arc discharge, and surrounding the other end of the main body. The shape of the tip side has an inner space substantially similar to the shape of the nozzle electrode, a shield cup detachably fixed to the main body, and provided on the outer cylinder of the main body, argon gas is introduced. Flows between the outer cylinder and the inner cylinder, and is ejected from the tip side of the nozzle electrode to the work surface. A first introduction part for, provided between the shield cup and the nozzle electrode tip side,
A second introduction unit for introducing a mixed gas of argon gas and hydrogen gas, flowing the mixture gas between the nozzle electrode tip side and the shield cup, and ejecting the mixture from the nozzle electrode tip side to a work surface, It is configured to perform melting and processing by the arc discharge in a state where the work is melted by laser light irradiation.

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(2) The melting apparatus using the laser beam and the arc according to (1) above, wherein the tip side of the nozzle electrode is made of a tungsten material.

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(3) The melting apparatus using the laser light and the arc according to (1), wherein the laser light source is a YAG laser or a carbon dioxide laser.

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[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of a melting apparatus using a laser beam and an arc according to the present invention will be described below in detail with reference to the accompanying drawings. FIG. 1 is a configuration diagram of a partial cross section showing an embodiment of a melt processing apparatus using a laser beam and an arc according to the present invention. FIG. 2 also shows FIG.
Is a simplified cross-sectional view of the melt processing unit (torch unit) 10 of FIG.

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Although the preferred embodiment of the melt processing apparatus using a laser beam and an arc according to the present invention has been described above, this is merely an example, and various modifications can be made in accordance with a specific application. Of course.

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[0037]

As described above, the melting processing apparatus using the laser beam and the arc according to the present invention effectively uses both the laser beam energy and the discharge arc energy, so that the melting processing efficiency is remarkably increased. Be improved.

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Claims (10)

[Claims] 1. A laser light system for converging and irradiating a laser beam from a laser light source via an optical system onto a work, and facing the work in a substantially coaxial positional relationship with an optical axis of the laser light system. A nozzle electrode provided at a position and supplied with a high voltage for arc discharge, wherein melting and processing by the arc discharge are performed in a state where the work is melted by irradiation of the laser beam. Processing equipment using a laser beam and an arc. 2. An outer cylinder and an inner cylinder substantially coaxial with the outer cylinder.
An optical system for focusing and irradiating the laser light of the laser light source on the work from the opening and irradiating the laser light from the laser light source is installed inside the inner cylinder, and the outside of the laser light path near the opening is used for arc discharge. An arc-shaped nozzle electrode to which a high voltage is supplied is provided, and the laser beam and the arc are melted and processed by the arc discharge in a state where the work is melted by the irradiation of the laser beam. Melt processing equipment using. 3. The laser beam according to claim 1, wherein an inert gas is introduced substantially coaxially with the laser beam system, and is ejected from the opening onto the melted work surface. Melt processing equipment using arc. 4. The laser beam and the arc according to claim 1, 2 or 3, wherein an inert gas is introduced substantially coaxially with the laser beam system and ejected to the nozzle electrode and the work surface. Melt processing equipment used. 5. The melting processing apparatus according to claim 3, wherein the inert gas is an argon gas. 6. A melting processing apparatus using a laser beam and an arc according to claim 4, wherein said inert gas is a mixed gas of argon gas and hydrogen gas. 7. The melting apparatus according to claim 1, wherein the work side of the nozzle electrode is made of a tungsten material. 8. The melting apparatus according to claim 1, wherein the laser light source is a YAG laser or a carbon dioxide laser. 9. A high voltage for arc discharge is supplied in a substantially coaxial positional relationship with an optical axis of a laser light system for focusing and irradiating a laser light from a laser light source via an optical system on a work. A melting processing method using a laser beam and an arc, wherein a nozzle electrode is opposed to the work, and the work is melted and processed by the arc discharge in a state where the work is melted by the irradiation of the laser beam. 10. The melting method using laser light and an arc according to claim 9, wherein an inert gas is jetted onto the melted work surface and the nozzle electrode.