DE900120C - Electric welding process - Google Patents

Description

Electric welding process Trying to improve the performance in the electric To increase welding, ever stronger currents are used when welding Reach 3,000 A under a layer of powder. Such high currents require, apart from that from the greater energy consumption, possibly an undesirably large penetration. To reduce the latter, cumbersome and expensive devices are necessary, namely with build-up welding and especially when the weld seam is metallurgical should be composed differently than the workpiece.

The invention relates to an electric welding method for high Amperages with a metal electrode that are applied to the workpieces to be welded applied slag-forming welding powder is immersed in such a way that the weld is completely covered by the welding flux. The method according to the invention enables es, the relationship between penetration and application, even with very strong currents easy way to regulate and achieve this by being on the welding track or metal profiles are arranged within the weld joint, which .under the action the electrical current and, if necessary, the overheated melt of the resistance mass become liquid and, depending on their quantity, reduce the penetration to a greater or lesser extent and the job more or less. raise. This as a result of their double effect very sensitive regulation can be used both in the case of migratory as well as can be carried out with the electrode stationary. In the latter case, the metal profile will be the welding point is fed to the workpiece. Here, the proportion of the metal profile can be regulated on the order by the fact that it is at one of the welding speed different speed is fed. In this way you can use an and achieve different effects with the same metal profile. In any case, the Method according to the invention also an increase in performance with regard to the applied, Amount can be achieved.

In a further embodiment of the invention, the shape of the penetration be influenced by using special metal profiles that are inside the weld joint lie and their shape can be adapted. It can here, for. B. V- or X-shaped Profiles are used, eliminating certain difficulties that arise in the case of X-seams he-. give, be avoided at the same time.

The metal profiles can be used regardless of their shape be to close the weld joint downwards and such an outflow of the To prevent sweat pool.

The subject matter of the invention is illustrated, for example, in the drawing.

Fig. I and 2: show in cross-sections through the weld known regulation of the seam width when welding under a powder layer by means of Change in tension; Fig. 3 to 5 show cross sections as they arise in different Embodiments of the method according to the invention result; Fig. 6 shows in comparison FIG. 5 shows the weld seam occurring in the known method; Figures 7 and 8 show in comparison of the known and the invention embodiments in a X-seam; 9 shows a longitudinal section through the weld with the fixed Electrode and feed of the workpiece and the metal profile.

FIGS. I to 4 show the different relationships on flat sheet metal plates with build-up welding, the welding powder in FIGS. 3 and 4 of the simplicity is not illustrated for the sake of All cuts are based on the findings drawn on the results of the welding processes described below have been made. The workpiece is marked with i, the electrode with 2, the molten one and therefore used resistance mass with 3, the penetration with 4, the applied Metal denoted by 5.

The examples according to FIGS. 1 and 2 were carried out in a known manner, with a welding current of 100 A, an electrode 6 mm in diameter and a welding speed of 350 mm / m-in. In contrast, the welding voltage according to FIG. 1 was 30 V, according to FIG. 2 40 V. This difference results in a wider and flatter weld seam in the case of FIG. Fig. I Fig. 2 Welding voltage .... 30 V 40 V Electrode consumption or application quantity 570 9 / m 570 9 / m Consumption of cons Stand mass .. 365 g / m 913 9 / m Cross section of the trages ........... 8o mm2 8o mm2 Cross section of the melted part of the workpiece (Penetration) ....... 149.5 MM2 144.5 MM2 Ratio of up contribution to penetration i: 1.87 i: 1.8 Energy consumption .... 30 kVA / hour 4o kVA / hour As a result of the higher energy expended in the case of FIG. 2, neither an increase in output nor a regulation of the relationship between penetration and application can be achieved. The higher energy expenditure is practically only used to melt the additionally consumed welding flux.

In the exemplary embodiments of the method according to the invention (FIGS. 3 and 4), a welding current of 100 A, a uniform welding voltage of 30 V, an electrade 6 mm in diameter and a welding speed of 350 mm / min. worked, namely in the case of FIG. 3 with a rectilinear electrode, in the case of FIG. 4 with an electrode oscillating transversely to the welding direction, which made 70 oscillating movements of 12 mm per minute. In the axis of the weld seam, according to FIG. 3, a flat iron 6 with a cross section of 60 mm 2, according to FIG. 4, a flat iron 7 with a cross section of 82 mm 2 was placed on the workpiece.

The results are as follows, with the numbers for @ in the example of Figure 4 in parentheses. Welding voltage 30 (30) V, electrode burn-off 570 (57o) 9 / m, consumption of resistance mass 403 (4I5) 9 / m, cross-section of the order 16o (17o) mm2, cross-section of the penetration 70 (90) mm2; Ratio of the order to the penetration: 2.3: i (z, 9: i), energy consumption 30 (30) kVA / hour.

As can be seen, the penetration according to the method according to the invention with otherwise unchanged welding data, this is considerably reduced, which has a negative impact on the effect of the applied Flachelsenprofiles 6 or 7 is due to which heat of fusion required and in any case at the same time - increases the order and thus the performance. By appropriate selection of the metal profile and the welding data, according to the invention any desired relationship between penetration and application can be established, whereby Welding with strong currents, especially under a powder layer, can be regulated can be executed. The above show specified digits, that the effects are very substantial. The welding performance in build-up welding can be doubled or more without additional energy expenditure.

While a large penetration is often desired for joint welds because the welding performance can be increased by a small weld joint angle, penetration should be kept small in alloyed materials, with austenitic welding and on workpieces with a high phosphorus and sulfur content. How this is achieved within the meaning of the invention is shown in comparison by the examples according to FIGS. 5 and 6, in which the same welding data were used. According to Fig. 5, a V- or Y-shaped metal profile 8 is inserted for a one-sided butt weld, the legs of which rest against the flanks of the joint, so .that this is also closed, as was previously the case without such an insert by the two parts of the workpiece happens (Fig. 6). The distance a between the upper edges of the inserted profile in FIG. 5 is selected to be equal to the joint width in FIG. 6 in this example. The comparison data are as follows: Fig. 5 Fig. 6 Cross section of the trages (at Fig. 5 including the V-profile) Sao mm2 330 mm2 Cross-section of the melted parts of the Workpiece brand) ......... 470 mm2 66o mm2 Share of penetration in the melt pool .... 47.5 0/0 67.8% Ratio of up contribution to penetration i, i: ii: a As can be seen, the penetration is reduced to half by the inserted profile with otherwise the same ratio, the application naturally increased.

The sealing of the welding joint by the inserted metal profile, which prevents the weld pool from flowing out is of particular advantage with X-seams (Fig. 7), in which the formation of the butting noses the workpiece parts must be made very carefully so far in order to avoid a harmful Avoid gap. Such precise preparatory work: von Nasen is in accordance with the procedure the invention is no longer necessary because the inserted Y-profile 9 (Fig. 8), the closure takes over. In the present case, it is located with narrow flanges on the lower edges of the workpieces to be connected. On the opposite side, this is not the case : necessary because the seal is already through after the first welding process the first weld is given. If necessary, the Y-profile can be converted into a X-profile are designed.

The method according to the invention can also be used with a stationary electrode and moving workpiece are carried out, as shown in FIG. 9 for a circumferential seam build-up weld is shown schematically. The metal profile io is made according to the welding point the direction of rotation of the workpiece, as indicated by the arrows. Of simplicity For the sake of this, the welding powder is not shown. The feeding of the metal profile offers the possibility of getting by with a few profiles, since the one supplied by the profile Melt mass by choosing a feed speed that differs from the welding speed can be regulated.

: Instead of feeding the metal profile io horizontally, it can also be fed from above z. B. are fed in an inclined position, in which case a conductive one is advantageous Connection between him and the workpiece is provided. The metal profile can also be a common welding wire.

The alloy components required in the weld seam can be used in the profiles placed on the welding line or sunk into the welding joint be that z. B. Od only from alloy material such as nickel. Like. Can consist.

With the method according to the invention can without expensive, for special purposes built welding systems build-up welding with minimal penetration, austenitic Welds and welded joints with a higher phosphorus or sulfur content the same economy as normal welding at high currents in particular are carried out under a layer of powder.

Claims (1)

PATENT CLAIMS: i. Electric welding process for high currents with a metal electrode which is immersed in a slag-forming welding powder in such a way that the welding point is completely covered by the welding powder, characterized in that on the welding path. or metal profiles are arranged inside the weld joint, which become liquid under the action of the electric current and possibly the overheated melt of the welding powder and, depending on their amount, to regulate: the ratio between. The penetration and application are used. z. Welding method according to claim i, characterized in that: that the molten mass of the metal profile is selected by choosing one of. : the welding speed is regulated different speed of their feed. 3. Welding method according to claim i or a, characterized in that the electrode is given a pendulum movement transversely to the welding direction. q .. Welding method according to claim i, characterized in that metal profiles are used which lie within the weld joint and prevent the weld pool from flowing out, 5. Welding method according to claim 2, characterized in that the metal profile is fed in from above, for example in an inclined position, and a conductive one Connection between him and the workpiece is established. 6. Metal profiles for the method according to claims i to 4, characterized in that they have V-, X- or Y-shaped cross-section. Attached publications: German patent specifications No. 58o 231, 730 49, 638314-