JP4915766B2 - Laser-arc hybrid welding method - Google Patents

Description

  The invention of this application relates to a method for performing welding using heat generated by pulsed arc discharge, and a laser / arc hybrid welding method in which a pulse laser is irradiated synchronously to an arc generation part and its peripheral part on the surface of an object to be welded About.

  Laser welding uses a laser with a high energy density as the heat source, so that a deep penetration depth can be obtained at a high welding speed, and because the melting width is narrow, the heat effect and thermal deformation associated with welding are small and high quality welding is achieved. Part is obtained. On the other hand, this laser welding has disadvantages in comparison with the conventional welding method in terms of cost, such as high cost of the apparatus and high groove accuracy.

  On the other hand, arc welding is inferior to laser welding in terms of penetration depth, welding speed, thermal deformation, and thermal effects, but can be welded at low cost, and the composition of the weld metal can be controlled by the addition of filler wire and high groove There are excellent features such as not requiring accuracy. As a method utilizing the advantages of both laser welding and arc welding, there is laser / arc hybrid welding in which an arc and a laser are simultaneously irradiated onto the surface of an object to be welded.

In order to perform welding in a stable state by taking advantage of the advantages of this laser / arc hybrid welding, it is considered that control of the output of the arc and laser is indispensable, and many techniques relating to this point have been studied (non- Patent Documents 1 and 2). For example, a pulsed laser irradiation pulsed arc welding method that starts in synchronization with a laser output period Tr of a pulsed laser from the start point of a peak period Tp of pulsed arc welding or a predetermined delay time from the start point (Patent Document) 1) and 2) and the arc current is made into a pulsating current in which the period in which the base current flows and the period in which the peak current flows are repeated, and when the arc current becomes the peak current in synchronization with the pulsation of the arc current, A method of irradiating (Patent Document 3) and the like have also been filed.
: JP 2003-25081 A : JP-A-2004-9061 : JP 2003-311415 A : D. Petring et.al., Proc. Of ICALEO 2003, A-301 (2003) “Investigations and Applications of Laser-Arc Hybrid Welding from Thin Sheets up to Heavy Section Components”, Promoted by Laser Institute of America. : D. Petring et.al., Proc. Of PICALO 2004 “RECENT PROGRESS AND INNOVATIVE SOLUTIONS FOR LASER-ARC HYBRID WELDING”

  In laser / arc hybrid welding, an optical system such as a lens or a parabolic mirror is used in the vicinity of the weld. However, if a lot of spatter is generated from the weld, it is expensive. Since the optical instrument is damaged, it is necessary to suppress the occurrence of spatter as much as possible. Whether or not the spatter is generated greatly depends on how the droplets are detached from the welding wire, that is, the droplet transfer phenomenon. For this reason, as the arc heat source, for example, a method of dropping one droplet by one pulse using a pulsed arc whose voltage and current periodically change as shown in FIG. 1 and a method such as spray transfer are desirable. .

  Further, when only an arc is used as a heat source, the occurrence of spatter can be reduced by adjusting and optimizing the voltage and current waveforms as shown in FIG.

  However, when a laser and an arc (laser / arc hybrid) are used as the heat source, the droplet transfer becomes unstable due to the interaction between the laser plume and the arc, so that the electrode is short-circuited or spattered in the molten pool. Such an undesirable phenomenon occurred.

  The invention of this application reliably stabilizes such unstablely transferred droplets and greatly suppresses the occurrence of spatter, and reduces the amount of heat used to suppress thermal deformation and thermal effects. Laser-arc hybrid welding method is provided.

  The invention of this application is to solve the above-mentioned problems. First, in the laser-arc hybrid welding method in which the pulse laser output is changed in synchronization with the pulse arc current and the pulse arc voltage, the arc output is the base output. Provided is a welding method in which a laser output is changed from a peak output to a base output at a point in time delayed from a point at which the peak output is changed to a peak output.

  Second, the laser-arc hybrid welding method described above in which the base output of the laser is zero is provided.

  Third, the laser-arc hybrid welding method is provided, wherein the delay time from the time when the arc output changes from the base to the peak to the time when the laser output decreases from the peak to the base is in the range of 0.01 ms to 50 ms. To do.

  Fourth, the delay time from the time when the arc power changes from the base to the peak until the time when the laser power falls from the peak to the base is 0.01% to 50% with respect to the time of the peak current and the peak voltage. A laser-arc hybrid welding method as described above is provided.

  According to the invention of the first laser / arc hybrid welding method, it is possible to provide a welding method in which the generation of spatter is significantly suppressed and the amount of heat to be used is small and thermal deformation and thermal influence are suppressed.

  According to the invention of the second laser / arc hybrid welding method, in addition to the above effects, the generation of spatter, thermal deformation and thermal influence can be further suppressed by setting the laser base output to zero.

  According to the third and fourth laser-arc hybrid welding inventions, in addition to the above-mentioned effects, it is possible to easily generate spatter by specifying the delay time until the laser output decreases from the peak to the base. Can be suppressed.

  The invention of this application reduces the pulse laser output when the pulse arc output is large, and increases the pulse laser output when the pulse arc output is small, thereby efficiently covering the laser without being absorbed by the arc plasma. It is characterized by irradiating the welding material. Further, the invention of this application is that the generation of the laser plume is suppressed by reducing the laser output to 0 or close to 0 after a short time has elapsed since the pulse arc output rose from the base to the peak. It is also characterized in that the occurrence of spatter is suppressed by smoothly transferring droplets without lowering.

  In the invention of this application, by providing such a configuration, it is possible to suppress short circuit and unstable fluctuation of arc length, and to significantly suppress the occurrence of spatter, and at the same time, with a smaller amount of heat. Since deep penetration welding is possible, there is a feature that thermal deformation and thermal influence due to welding can be reduced. The invention of this application is characterized in that welding is performed using a heat source in which the output of the laser is changed so as to be synchronized with the arc voltage and the arc current. This will be described in more detail.

  FIG. 1 schematically shows arc voltage and arc current at the time of pulse arc welding. When laser-arc hybrid welding is performed using a pulse arc, arc (2) is a normal diagram when the peak arc is output. As shown in FIG. 2, it occurs toward the extension of the wire (4). On the other hand, since the arc (2) at the time of base arc output has a low arc voltage, the material to be welded is energized through the laser plume (3) in which a large amount of metal vapor having a low ionization voltage exists as shown in FIG. To do. For this reason, the arc (2) is stably and continuously supplied to the material to be welded even at the base output where the voltage is low.

  However, when the laser (1) output becomes high or the composition of the material to be welded contains an element that easily evaporates, the laser plume (3) formed by the laser (1) becomes large, and the peak arc The arc (2) may continue to energize the laser plume (3) during output. Fig. 4 shows the arc voltage-current characteristics at the time of peak arc output and base arc output in laser-arc hybrid welding. At peak arc output, arc (2) is usually shown in Fig. 2. Since it is generated toward the extension of the wire, it operates at point A having a relatively short arc length. However, when the base arc is output, the arc (2) passes through the laser plume (3) and the material to be welded is substantially energized. The length increases and the operation is performed at point B in FIG. When welding is normally performed, stable droplet transfer is performed by alternately repeating the points A and B.

FIG. 5 shows the waveform of the arc voltage and current when welding is normally performed. The arc is in the state shown in FIG. 3 during a very short time t _{1 after} the arc output is switched from the base to the peak. From FIG. 2, it is shown that a normal large arc (2) current flows.

In this laser / arc hybrid welding, when a large laser plume (3) is formed or when the arc voltage at the peak is small, the arc output shifts from the base to the peak as shown in FIG. Since the arc (2) continues to be energized in the laser plume (3), the actual arc length becomes longer and the operating point at the peak output becomes the point C in FIG. 4 and the current is extremely small. Become. Figure 6 is shows the waveform of arc voltage and arc current at this time, per pulse current is low because the arc output time arc t ₂ after switching to the peak from the base energized through the laser plume The accumulated current value becomes extremely small, melting does not proceed at the tip of the wire (4), and the droplet cannot be detached from the tip of the wire.

  FIG. 7 shows a state in which this phenomenon continues, but a low current flows over three pulses. For this reason, the melting of the wire hardly progresses during this time, and the wire is sent at a constant speed, so that the wire and the molten pool are short-circuited at the position indicated by the star (*) in FIG. It is shown that it is in the state.

  FIG. 8 schematically shows the state of the arc voltage, arc current and laser output in the invention of this application. However, the invention of this application shows that the output waveform as shown in FIG. It goes without saying that this can also be achieved with any other waveform.

The invention of this application suppresses the generation of the laser plume by reducing the laser output to 0 or a small value after a lapse of a short time t _d when the arc output rises from the base to the peak. The present invention provides a laser-arc hybrid welding which can surely suppress the phenomenon that the arc current due to the interaction between the two becomes low and smooth droplet transfer is not performed.

  The invention of this application will be described in more detail with reference to examples.

Laser-arc hybrid welding was performed using a pulsed arc with a peak voltage of 43 V, a base voltage of 15 V, a repetition frequency of 111 Hz, and a duty cycle of 30% and a CO ₂ laser. As a base material, JIS SM490A was used, and the distance between the arc and laser irradiation positions was 3 mm, the welding speed was 3 m / min, and welding was performed with an arc leading. Laser in the case of constant power of 5 kW, arc phase opposite to change the output of the laser as shown in FIG. 8, and sets the time t _d to 0.5 ms. The laser peak power was 5kW and the base power was zero.

  FIG. 10 shows the result when a laser with a constant output is used. Even in the peak arc output region, the state where the arc continues to energize the laser plume may continue, and the arc current is extremely reduced and droplet transfer occurs. It is shown that there is much spatter generation because it is not stable.

  On the other hand, FIG. 9 shows the result in the case of using the laser output fluctuation according to the invention of this application, but when the laser output is reduced from 5 kW to 0, the arc surely starts from the state of FIG. Transition to the state of FIG. 2, the same arc current always flows stably in a pulse shape, the droplet transfer is very stable, and almost no spatter is generated.

  According to the invention of this application, since laser-arc hybrid welding can be performed with a small amount of heat, deformation and thermal influence associated with welding can be reduced. In addition, stable droplet transfer is possible, and high-quality welds can be obtained at a lower cost.

The aspect of the arc voltage and arc current at the time of pulse arc welding is shown. This shows the behavior of the arc during peak arc output during laser-arc hybrid welding. It shows the behavior of the arc when the base arc is output during laser-arc hybrid welding. This shows the voltage-current characteristics at peak output and base output during pulse arc welding. The waveforms of arc current and arc voltage in the normal state during laser / arc hybrid welding are shown. The waveforms of arc current and arc voltage at the time of abnormality during laser / arc hybrid welding are shown. The waveforms of arc current and arc voltage at the time of abnormality during laser / arc hybrid welding are shown. The waveform of the arc voltage, the arc current, and the laser output during the laser-arc hybrid welding of the present invention is shown. The waveform of the arc voltage, the arc current, and the laser output when the laser output of the present invention is varied is shown. In laser-arc hybrid welding, the arc voltage, arc current, and laser output waveform when the laser output is constant are shown.

Explanation of symbols

1: Laser 2: Arc
3: Laser plume 4: Wire 5: Droplet

Claims (4)

In the laser-arc hybrid welding method in which the pulse laser output is changed in synchronization with the pulse arc current and the pulse arc voltage , the pulse laser output is decreased when the pulse arc output is large, and the pulse laser output is decreased when the pulse arc output is small. greatly, and welding method arc output is characterized by changing the base output the laser output from the peak power at the time delayed from the time of changes in the peak output from the base output.
The laser-arc hybrid welding method according to claim 1, wherein the laser base output is zero. 3. The laser according to claim 1, wherein the delay time from the time when the arc output changes from the base to the peak to the time when the laser output decreases from the peak to the base is in the range of 0.01 ms to 50 ms. -Arc hybrid welding method. The delay time from the time when the arc output changes from the base to the peak to the time when the laser output decreases from the peak to the base is in the range of 0.01% to 50% with respect to the time of the peak current and the peak voltage. The laser-arc hybrid welding method according to claim 1 or 2.