DE19527070C1 - Welding process with several high energy beams, esp. laser beams - Google Patents

Abstract

In this welding process by means of several high energy welding beams, in particular laser beams, the welding beams are simultaneously projected onto two opposite outer surfaces of the workpiece, inducing a plasma therein, and both welding beams are controlled depending on the permeability of steam diffusion capillaries formed by both beams. The permeability of the steam diffusion capillaries is monitored by measuring plasma fluctuation. In order to better sense the permeability of the steam diffusion capillaries, the welding process is carried out in such a way that an indicative frequency is modulated onto the high energy radiation of at least one welding beam, and/or in that the frequency spectrum of at least one welding beam has a characteristic frequency that distinguishes it from the other welding beam. The indicative frequency and/or characteristic frequency are determined from the welding plasma at the outer surface of the workpiece opposite to the welding beam that is modulated and/or has a characteristic frequency.

Description

The invention relates to a welding process several high-energy welding beams, especially lasers radiate with the welding beams simultaneously on two opposite workpiece outer surfaces plasmaindu radiate radiantly, and in which the radiation power at least one of the two welding beams forming a steam capillary is modulated in time, whereby the patency of the steam capillaries is monitored by measuring the plasma fluctuation.

A welding process with the aforementioned features is known from DE 42 16 643 A1.  

The well-known passage capability measurement shows only a considerably restricted Accuracy on.

The invention is therefore based on the object a process with the above-mentioned process steps to improve so that the accuracy of the measurements significantly can be increased.

This object is achieved in that the high energy radiation of at least one welding beam over the flood tuationsfrequenzen the welding plasma lying indication frequency is modulated.

In the above-described method, the through are no longer Fluctuations in intensity of the laser-induced welding plasma occurring Plasma fluctuation frequencies, typically in the range of up to 10 kHz, even used for patency of the steam capillary. Rather, it will be a special one Indicator used. The high energy radiation becomes modu liert. The modulation is such that an indication frequency used outside the frequency range of plasma fluctuation becomes. Because the indication frequency deviates or higher, is by determining their occurrence given a sure sign that the steam capillary is consistent. The detection of the capillary Commonness are improved so far that qualitative and quantitative determinations of the patency of the steam capillary laren in the process-accompanying analysis to control the both welding beams are decidedly improved. It will  enables a comprehensive quality assurance system in which the detection of the indication frequency is possible in real time. This can interfere with the beam paths of the high energy welding beams can be avoided.

The welding process can be improved in that that frequency is used as the indication frequency, those for setting the average laser power of an HF-on excited laser with a pulse width modulation method serves. The frequency for setting the middle laser line of an RF-excited laser, i.e. a laser with high frequency excitation, stands for the execution of the welding process driving readily available. It modulates itself Welding radiation without further exposure, therefore requires radiation mutually no special measures because they are due to the Pulse width modulation method is present anyway. It is important that the laser power density spectra of the two Lasers are different and especially those used as indications frequency used frequency or several such indications frequencies is only contained in the spectrum of a laser or are.

Of the aforementioned typical plasma fluctuation frequency frequency range for laser beam welding gives way to a frequency sufficiently from 50 kHz and does not have the consequence that to ih Mastery in the hardware area special measures should be hit. It is therefore advantageous that sweat proceed in such a way that a Frequency of 50 kHz is used, which at the same time setting the mean laser power with a Pulse width modulation is used.

It is advantageous to carry out the welding process in this way ren that one of the two welding beams from a DC-ange excited laser and the other of the two welding beams from an RF-excited laser is generated, and that the measurement from the workpiece side of the DC-excited laser. As a result of the different excitation of the welding beam len generating lasers arise on the two correspond corresponding workpiece sides different fre  frequency spectra. On the workpiece side of the DC-excited La sers is the frequency spectrum of the RF-excited laser from Certainly not available from home and in particular missing in the frequency spectrum of the HF-excited laser sustained modulation frequency of approx. 50 kHz. One is therefore early disturbance of the measurement result on the workpiece side of the As a result, DC-excited laser is excluded.

To further reduce the measurement interference, the welding process is carried out so that radiation radiation sensor outside the radiation range of the one excited by the HF Laser induced plasma is applied. As a result also from the high-energy radiation excited by the HF in induced plasma do not falsify the measurement.

A convenient implementation of the measurement from the factory This makes it the piece side of the DC-excited laser is enough that a radiation sensor next to the laser radiation of the DC-excited laser close to the measurement of the latter indu decorated plasma is arranged. With this arrangement of the Radiation sensor is a direct measurement of high energy radiation from one side of the workpiece through the steam capillary excluded on the other side of the workpiece. A lot more is used that a part of the RF-excited La laser radiation penetrates the vapor capillary and intensity fluctuation in the plasma of the DC-excited laser gen with the frequency of indications caused by the in Radiation sensor in question can be detected. It can also a coupling of the existing on the two workpiece sides which are suitable for plasmas.

The welding process can be done with simple constructional be carried out if a Fo todiode with a spectral sensitivity limiting Filter is used. With the spectral sensitivity limiting filter, the load on the photodiode is reduced graces and their relative sensitivity to measure the frequency range increased, which the measurement result of Consistency benefits.  

The welding process can be designed accordingly that indicates the continuity of the steam capillary Signals are generated by due to in the steam capil lare penetrating indication frequency modulated Hochener radiation generated sensor signals in relation to the indicati frequency can be set. As a result of the reference to the Signal frequency results in clearly evaluable signals the in the control process for the two welding beams with greater accuracy can be used.

For on-line control of the two welding beams the welding process is preferably carried out so that the Relocation of the signals after the lock-in procedure leads. This method is particularly suitable for real-time control of the two welding beams with the desired qualitative and quantitative accuracy ability to perform.

The invention is based on a Darge in the drawing presented embodiment explained. It shows:

Fig. 1 is a schematic representation of an arrangement for carrying out the invention Schweißverfah Rens,

Fig. 2 is a schematic representation of frequency-dependent power density spectra to explain the determination of the patency of the steam capillary, and

Fig. 3 measurement results of the arrangement of Fig. 1 as a function of time.

Fig. 1 shows a workpiece with two mutually deviated workpiece outer surfaces 12 , 13 , act on the high-energy welding beams 10 , 11 . The action takes place simultaneously and leads to the formation of laser-induced plasmas 15 , 22 to a vapor capillaries 14 , which has been enlarged and shown continuously in the schematic representation. The area of the workpiece 23 which is dashed in FIG. 1 is intended to symbolize the melting zone.

The simultaneous or simultaneous welding of the workpiece from both workpiece sides 18 , 19 brings about a symmetrical introduction of heat and has a symmetrical seam with such a residual stress field. A steam capillary open on both sides enables almost complete outgassing. Due to the special boundary conditions of the heat conduction, the degree of overlap in the center of the joint or in the center of the workpiece can be achieved with less energy expenditure than if welding is carried out in succession from the two workpiece sides. The process efficiency of the simultaneous welding on both sides therefore exceeds the process efficiency of the one-sided welding and the bilateral sequential welding.

In order to achieve the continuity of the steam capillaries 14 shown in FIG. 1, the high-energy welding beams 10 , 11 must be controlled so that they are aligned. For this purpose, a processing head containing the focusing optics 24 and 25 , respectively, must be controlled accordingly for each of the welding devices which are not shown in detail in the rest. The control can be carried out in a conventional manner by means not shown as a result.

The high-energy welding beams 10 , 11 are provided by corresponding high-energy generators, for example lasers 1 and 2 . From the lasers 1 , 2 , laser radiation is fed via deflecting mirrors 16 , 17 to the respective focusing or processing optics 24 , in each of which a further deflecting mirror 24 ', the beams 10 , 11 the actual focus sierspiegel 24 ''which supplies the radiation the machining point of the workpiece 23 is focused, that is, that area in which the steam capillary 14 is shown in FIG. 1.

The laser 1 is RF excited. Its average power is set using a pulse-width modulation process that works at a frequency of approx. 50 kHz. The laser 2 is DC-excited, that is to say continuous, and does not have the above-mentioned modulation spectrum, that is to say in particular it does not have a dominant peak in the range of 50 kHz as the laser 1 has.

If with the lasers 1 , 2 a welding process with the formation of laser-induced plasmas 15 , 22 is introduced over the workpiece 23 , the frequency contained in the frequency spectrum of the HF-excited laser is approximately 50 kHz in the power density spectrum of the radiation of the plasma 15 again. In contrast, the power density spectrum of the plasma 22 has no significant peaks in the corresponding frequency range, as long as both welding plasmas 15 , 22 are decoupled to the left and right of the workpiece, because the vapor capillary 14 is impervious. If the lasers 1 , 2 are controlled so that their performance is sufficient to produce a continuous vapor capillary 14 and the high-energy welding beams 10 , 11 are aligned, then a plasma coupling takes place or it penetrates part of the modulated laser radiation of the RF-excited laser 1 the steam capillary and causes intensity fluctuations in the radiation of the plasma 22 with the modulation frequency on the workpiece side 18 of the unmodulated laser beam 10 . This can then be detected there and thus has the quality of an indication frequency, by the determination of which it can be reliably established that the steam capillary 14 is continuous.

To determine the indication frequency on the workpiece side 18 , a radiation sensor 20 is provided in the form of a photodiode, which is arranged next to the welding beam 10 in Meßnä he to the plasma 22 . The photodiode is an optical filter 20 'upstream to limit their spectral sensitivity speed. The radiation sensor 20 emits sensor signals S2 which have the dication frequency in the case of continuity of the steam capillaries 14 .

In order to rule out disturbances in the measuring accuracy, the radiation sensor 20 is positioned on the workpiece side 18 in such a way that it cannot be reached by radiation from the plasma 15 . For this positioning, the arrangement behind the workpiece 23 is generally sufficient, which acts as a visual barrier and does not allow radiation of the plasma 15 to reach sensor 20 .

Signals S2 can be used to influence the welding process, in particular the two welding beams 10 , 11 . In the presence of a signal S2 with frequency indications, for example, the average power of the laser 1 can be reduced if this was previously increased in order to achieve a continuity of the steam capillaries 14 . The welding beams 10 , 11 can also be controlled in the sense that their position is changed so that the portions of the steam capillaries that are due to them are aligned in order to achieve an overlap of the root regions of the individual capillaries.

Fig. 2 shows explanatory diagrams of the power density spectrum (L density) as a function of the frequency for the two plasmas 15 , 22 with a continuous and impervious capillary. In both cases, a pronounced 50 kHz peak is present on the workpiece side 19 , where the plasma 15 induced by the HE-excited laser 1 is located. On the opposite workpiece side 18 , the plasma 22 induced by the DC-excited laser 2 , however, only has a 50 kHz peak if the capillary is continuous. The presence of this indi cation frequency on the opposite side of the laser 1 work piece side 18 can thus be determined with certainty by measuring the continuity of the steam capillary ren 14 .

The necessary control of the lasers 1 , 2 or the high-energy welding beams 10 , 11 can be carried out on the basis of signals S2. However, there is an increase in the measuring sensitivity if the sensor signal S2 is set in relation to the indi cation frequency. To this end 1 is shown in Fig. Darge provides that the laser 1 enters a pulse width modulation signal as a reference in a lock-in amplifier 26, which outputs an OFF output signal S3, which indicates the continuity of the pillaren Ka. For the meaning of this signal S3, reference is made to FIG. 3, which shows the intensity of the high-energy welding radiation as a function of the time of the welding process. The signal S2 corresponds to the radiation intensities of the plasma 22 recorded with the radiation sensor 20 , that is to say contains the indication frequency which originates from the laser 1 . The signal S1 corresponds to the radiation intensities of the plasma 15 , which were recorded with the radiation sensor 21 . Both signals are generated by means of the measuring amplifiers shown in FIG. 1.

The signals S1, which contain the pulse-width modulation signal of the laser 1 , that is to say the indication frequency, show that the laser beam 11 was switched off during the time intervals 3 to 4 s and 6 to 7 s to during this time to maintain an impervious steam capillary. In contrast, the signals S2 are present throughout the entire welding time of approx. 0.2 to 8.5 s. With appropriate use of the lock-in technique, this results in the course of the signals S3 for the capillary patency. It can be clearly seen that during the times of the high level of approx. 0.2 to 3 s, of approx. 4 to 6 s and of approx. 7 to 8.5 s there is capillary patency, in contrast to the times of approx 3 to 4 s and from about 6 to 7 s, in which a low level is given and consequently the non-continuity of the steam capillaries 14 is indicated.

The power density spectra mentioned in relation to FIG. 2 can be determined in a suitable manner. For example, fast Fourier transforms (FFT) can be performed off-line in computer-aided analyzes. Spectrum analyzers are suitable for real-time control of the two welding beams 10 , 11 , such as the lock-in amplifier 26 shown schematically in FIG. 1.

The regulated welding process described above allows on-line quality assurance for simultaneous welding with High energy welding beams. The process can be used for optimization of process parameters, for process data acquisition and who are used for use in controlling the process the. The welding process is particularly useful when welding used with CO₂ laser radiation, namely in manufacturing open carrier and semi-finished products, as well as in section production in steel and shipbuilding, in the offshore area, in wagon and Body construction as well as lifting and conveying facilities. At all of the welding processes that can be used for this purpose can  all accessible on both sides, fully connected Bump configurations from the advantages due to the improvement the patency measurement of the steam capillaries be made. This also applies to configurations where the high-energy welding beams due to the process under one Angle of incidence of more than 10 ° to the surface normal of the the workpiece surface exposed to radiation need to be, e.g. B. when welding T-joints in heavy plate Area.

Claims (9)

. Welding method with several high-energy welding beams ( 10, 11 ), in particular laser beams, in which the welding beams ( 10, 11 ) simultaneously irradiate two workpiece outer surfaces ( 12, 13 ) opposite each other and in which the beam power of at least one of the two, a steam capillary ( 14 ) forming welding beams ( 10, 11 ) is modulated in time, the continuity of the steam capillaries ( 14 ) being monitored by measuring the plasma fluctuation, characterized in that the high-energy radiation of at least one welding beam ( 10, 11 ) lies above the fluctuation frequencies of the welding plasma Indication frequency is modulated. 2. Welding method according to claim 1, characterized in that that frequency is used as the indication frequency, which serves for setting the mean Laserlei stung an RF-excited laser ( 1 ) with a pulse-Wei ten-modulation method. 3. Welding method according to claim 1 or 2, characterized records that a frequency of 50 kHz is used. 4. Welding method according to one of claims 1 to 3, characterized in that one of the two welding beams ( 10 ) by a DC-excited laser ( 2 ) and the other of the two welding beams ( 11 ) by an HF-excited laser ( 1 ) is generated, and that the measurement is carried out from the workpiece side ( 18 ) of the DC-excited laser ( 2 ). 5. Welding method according to one of claims 1 to 4, characterized in that the measurement is carried out with a radiation sensor ( 20 ) which is arranged outside of the radiation range of the RF-excited laser-induced plasma ( 15 ). 6. Welding method according to one of claims 1 to 5, characterized in that the measurement is carried out with a radiation sensor ( 20 ), the ne ben of the laser radiation ( 10 ) of the DC-excited laser ( 2 ) in close proximity to the plasma induced by the latter ( 22 ) is arranged on. 7. Welding method according to one of claims 1 to 6, characterized in that the measurement is carried out with a radiation sensor ( 20 ) having a photodiode with a spectral sensitivity limit filter ( 20 '). 8. Welding method according to any one of claims 1 to 7, as by in that the continuity of the vapor capillary (14) indicating signals (S3) are generated by a result of the vapor capillary (14) eindrin gender indication of frequency-modulated Hochenergiestrah lung sensor signals generated ( S2) in relation to the indication frequency. 9. Welding method according to claim 8, characterized net that in relation to the signals (S2, S3) after the Lock-in procedure is carried out.