DE974135C - Sheathed electrodes with unalloyed or alloyed core wire and with acidic, oxidic ores and envelopes containing a substantial proportion of metal powder - Google Patents

Description

Sheath electrodes with unalloyed or alloyed core wire and with containing acidic, oxidic ores and a substantial proportion of metal powder Coverings The core wires have been known to date as deeply burn-in electrodes, which have a low welding speed due to their core made of non-metallic materials, an arc voltage of about 17 to zg volts and one that shorts the current Have drop transfer. The long unobstructed burning time of the arc between two drop transitions causes a deep burn-in into the base material. Also certain medium-thick coated American electrodes, which have significant proportions contain cellulose in the jacket, result in a deep penetration. Your welding arc has a voltage of - 6 to 32 volts. The achievable welding speeds with Core wires or with the American electrodes are modern requirements no longer grown. In addition, it is dynamically stressed for the production Welded seams demanded electrodes that burn in even more deeply.

These two demands for high welding speed and deep Penetration could not be achieved so far, because only slowly welding Seams made with electrodes show a relatively deep penetration. Under Penetration is the depth of the molten base material, measured in millimeters, Understood. With the usual deep burn-in electrodes it was 3o to ¢ o ° / ° of the respective wire diameter.

An electrode with which the two requirements can be met must have a high arc voltage in order to be able to melt away quickly, and also allow a high current load to burn deeply. Under current load be the density of the current required for welding in amperes per mm2 wire cross-section Understood.

A high arc voltage can be caused by the presence of silica (Si02) can be achieved in the shell, because the ionization work and thus the ionization voltage the silica is very high. Their share in the shell should be about 7 to 15 ° / °. Larger amounts cannot be used because the silica is heavy melting slag results. In order to be able to keep the slag thin, is about twice to three times the amount of rutile (Ti02) of silica necessary, and about 15 to 35 ° / °. The presence of rutile makes it acidic the jacket is preserved, but the arc voltage is reduced. To a high arc voltage the effect of the quartz alone is too weak.

In-depth studies have shown that additions of steel in powder form with 0.2 to 0.35 ° / ° C, at least 0.25 ° / ° Si and at least 0.20 / 0 Mn in amounts of 35 to 700 /, to the shell increase the arc voltage. The per se known additions of iron powder to electrode sheaths do not show this effect.

The iron powder types available on the market have contents of impurities, in particular oxygen contents that are higher than those in commercially available Steels are allowed at most. In coming to use according to the invention However, powders may contain the proportions of impurities, e.g. B. of oxygen, the Do not exceed the maximum permissible limit for commercially available steels.

The invention thus relates to sheath electrodes with unalloyed or alloyed core wire and with acidic, oxidic ores such as quartz and rutile, as well as sheaths containing a substantial proportion of metal powder, and the invention consists in that these sheaths 35 to 7o ° / ° steel in Contain powder form, which consists of 0.2 to 0.35 ° / ° C, at least 0.250% Si, at least 0.22 / ° Mn, the remainder iron and unavoidable impurities.

The steel used according to the invention preferably contains 0.2 to 2.0 Mn in powder form. Manganese contents of about 0.5 ° / ° are particularly favorable. There is no need to add ferromanganese to the shell when using steel in powder form.

It is known to use calcareous shell compounds in amounts up to zo ° / ° of the shell weight steel or pig iron powder with 0.05 to 504 C, o, z to 30 /, Si, 0.05 to 6 ° / ° Mn and at most 0, Add 5 ° / ° oxygen.

A sheath electrode with a wire diameter of ¢ mm and a sheath which consisted of 10 ° / ° Si 02, 38 °% rutile (Ti 02) and, according to the invention, of 5 ° / ° steel in powder form at 0.24 ° / oC and 0.5% Mn, resulted in an arc voltage of 38 to ¢ o V with an arc length of about z mm, while under the same conditions the arc voltage was only 32 to 35 volts with the same clad electrode with conventional iron powder addition. With the latter electrode, the arc was often interrupted by short circuits.

By adding steel in powder form with even higher carbon contents to the electrode sheaths, the welding speed could be increased further and the penetration deepened, which was already 80 to zzo ° / ° of the wire diameter at 0.240 / 0 C. A carbon content above 0.35 % proved to be disadvantageous, however, since the welds became sensitive to hot cracks, which is particularly the case when welding alloyed steels.

The high arc voltage of the coated electrodes according to the invention with acidic and powdered steel coats caused a drizzle Transfer of very many small droplets, which as a result of the high vapor pressure in the Arcs have significant kinetic energy. The drops are so small that even with very short arcs no drop transitions short-circuiting the current can arise. This fact means that the electrode with very short arc and even dragged in contact with the workpiece without the arc going out or the electrodes on the workpiece stick. The very short arc, the length of which is usually x mm or less - a small crater at the end of the electrode determines this length - has a very small one electrical resistance. Thus, the column of the arc has a high conductivity for the electric current. This makes it possible to use the electrodes to be welded with high current densities and to achieve a deep penetration. the The current density in the above-mentioned electrode with a wire diameter of ¢ mm about 16 to z9 Amp./mm2, while the previously usual deep burn-in Electrodes 12 to z ¢ Amp./mm2.

From studies with contact welding rods it was known that by Reduction of the wire diameter and by accommodating this reduction corresponding amount of metal in powder form in the sheath the voltage of the exclusively Burning arc on the core wire surface and with this the penetration comparatively is increased.

According to the invention, however, with core wire diameters of the same size and with the same proportions of metal powder in sheaths of the same thickness the Arc voltage increased by using steel instead of conventional iron powder in powder form with a certain composition, in particular with 0.2 to 0.35 ° / ° C, is chosen.

The electrode jackets according to the invention have because of their high content very good electrical conductivity on steel in powder form, which is also due to Heating to high temperatures is not significantly reduced. Try, Welding these electrodes in machines resulted in an increase in the deposition rate, because with this welding process the current load is higher than when welding Can be hand selected. Because of the possibility of these electrodes in contact to be able to weld slowly with the workpiece and because of the high content of steel in powder form in the casing, which enables the transmission of electricity, these electrodes are particularly suitable for automatic welding. Desirable However, for this welding process the electrodes would be without damaging the To be able to reel electrode sheaths.

The solution to this problem is a further development of the present one Invention. It was found that the automatic welding more than 35% proportion of steel in powder form wholly or partially through a steel wire wound around the core of the electrode can be replaced.

This exchange option is now used to to wrap the core wires of the electrodes with a steel wire in a manner known per se and only then to apply the sheath compound, whereby it is achieved that a winding the electrodes without damaging the sheaths.

It is known per se in automatic arc welding To use electrodes, their cores with steel wires of the same or different composition are wrapped. These wires remain visible on the outside after the coating has been applied and enable power to be drawn or transferred from the machine to the core wire.

The viscosity of the slag of the electrode sheaths can be influenced by additives can be regulated by up to 8 0 /, magnesium carbonate, while the AC weldability the electrodes is regulated by the addition of calcium silicate. Furthermore, the Electrode sheaths in ferro-molybdenum content up to q.0 / to improve toughness the weld and ferrochrome for alloying the weld metal are added.

The composition of the electrode sheaths, which according to the present invention can be used for sheathing unalloyed or alloyed core wires, is therefore as follows: Si02 ......................... 5 to 150 / 0 Ti OZ. . . . . . . . . . . . . . . . . . . . . . . . 12 to 35 0 /, Powdered steel. . . . . . . . . . . 7o to 35 0/0 Mg C 03. . . . . . . . . . . . . . . . . . . o to 8 0 /, Ferromolybdenum. . . . . . . . . . . . . . . o to 4 "/, A jacket with 10 0 /, S'021 28 0 /, Ti O2, 50 0 /, steel in powder form with 0.2q.0 /, C and 0.50 /, Mn, q.0 / proved to be particularly advantageous , Mg C03 and 20 /, ferromolybdenum. The electrode sheaths can also contain alkali salts, organic binders or inorganic binders such as water glass.

A further increase in the penetration depth can also be achieved through additives of gas-forming agents to the above-specified coating compounds in amounts of up to to 2o 0 /, of the dry coat weight can be achieved. These gas-forming agents can e.g. B. be powdered alfa cellulose or fine cotton particles, where Additions in amounts of 8 to 10% are particularly effective. A little less effective are z. B. beech and spruce wood flour. The achievable increase in the penetration depth is 2o to 5o 0 / ,.

The gas-forming agents can either be dry, previously untreated Form or in a mineralized state of the shell compound can be added.

The mineralization is done by stirring in the dry powder, for example alfa cellulose, in a solution of water glasses, if necessary with additions of magnesium silicates. The cellulose or wood flour particles are then exposed to a swelling time of up to 25 hours. This overdrawn These particles are covered with a thin mineral layer, which is moving too quickly Burns in the arc protects.

These gas-forming additives are preferably used for welding in machines in the form of conventional coated electrodes or in the form of coated chains into consideration.

It is known that sheaths of welding rods other than slag-forming inorganic substances can also contain large amounts of organic substances, which evolve gas during welding, which releases oxygen and nitrogen away from the weld metal.

Claims (3)

PATENT CLAIMS: i. Sheath electrodes with unalloyed or alloyed core wire and with acidic, oxidic ores, such as quartz and rutile, as well as sheaths containing a substantial proportion of metal powder, characterized in that these sheaths contain 35 to 70% steel in powder form, which is composed of 0.2 to 0 , 35 0 /, carbon, at least 0.15 0 /, silicon, at least o, 20 /, manganese, the remainder iron and unavoidable impurities. 2. Clad electrodes after Claim i, characterized in that the steel added to the casing is in powder form 0.2 to 2%, preferably about 0.5% manganese. 3. Sheathed electrodes according to claims i and 2, characterized in that the electrode covering 5 to 15 0 /, SiO2, 12 to 35 0 /, Ti O2, 7o to 35 0 /, steel in powder form and optionally up to 80 /, Mg C03, up to q.0 /, ferro-molybdenum and additions of ferrochrome, calcium silicate, alkali salts and organic or inorganic binders such as water glass. q .. Covered electrodes according to claims i to 3, characterized in that the sheath is approximately 10 0 /, Si 0 " 28 0 /, Ti 02, 50 0 /, steel in powder form, q.0 /, Mg C03 and 2 0 5. Sheathed electrodes according to claims i to q., Characterized in that when welding in automatic machines the more than 35% amount of steel in powder form in the sheath is wholly or partially covered by a core wire around the electrode 6. Sheathed electrodes according to claims 1 to 5, preferably for welding in machines, in the form of conventional sheathed electrodes or in the form of sheath: etten, characterized in that the sheath to increase the penetration depth of Contains up to 20% of the dry shell weight 7. Sheath electrodes according to claims 1 to 6, characterized in that the gas-forming organic additives are mined to the sheath Claims 1 to 7, characterized in that the casing contains an additive of 8 to 10% of powdered alfa cellulose and / or fine cotton particles. Documents considered: Austrian Patent No. 165 696; French Patent Nos. 944 786, 897 025, 770 902; British Patent Nos. 3,762 / igii, 499,852, 5o2 823, 167 o63, 447 976, 490 403, 118 296, 415 0 35 U.S. Patent Nos. 2 009 240, 2 432 048, 1517 311, 1768 998, 1,760,534; Dr. F. Ropatz, "Die Edelstähle", 3rd edition, Berlin, 19493, Springerverlag, I. Division, lines i to 9, p. 198; Kieffer-Hotop, »Sintereisen und Sinterstahk, Vienna, 1948, p. 74, number table ix; Zeyen and Lohmann, "Schweiß der Eisenwerkstoffe", Verlag Stahl und Eisen, 1948, p. 55; »Philips tech. Rundschau ”, October 1946, pp. 304 to 309; »Material standards DIN 1661 <c, 1948, p. I25; Erdmann-Jesnitzer, "Material and Welding", Berlin, 295 "pp. 197/198 and 217.