DE1210101B - Inert gas arc welding process - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

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German KL: 21h-30/12

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1210101
Y661VHId / 21h
December 19, 1962
3rd February 1966

The present invention relates to a method for gas-shielded arc welding of steel.

In general, arc welding under a protective gas containing nitrogen becomes an unfavorable one Result achieved. There are usually pores in the deposited metal because the nitrogen does not enter the Atmosphere can escape if the solubility of gases in the weld metal as it solidifies reduced. However, it has been found that arc welding under protective gas gives better results can be achieved if nitrogen is added to the protective gas and at the same time to the welding wire a metallic element capable of forming a nitride is added. A stable nitride then forms this metallic element in the deposited metal, which prevents the formation of pores and tough weld metal is generated.

It is therefore the object of the present invention to obtain tough, strong weld metal that has a high Has notch toughness by causing the formation of a nitride in the weld seam. It is especially for welding high tensile steel and cold tough steel with high notch toughness suitable.

The invention consists in that in addition to the usual welding consumables nitride-forming metal and nitrogen during. of welding brings to the welding point so that the Nitrogen with the metal forms nitride, which is at least partially finely distributed in solid in the weld metal Phase is deposited.

An expedient development of the present invention consists in an inert gas arc welding Carry out with a protective gas that does not have to contain nitrogen, but a welding wire with a To use a soul that contains one or more nitride-forming metals and / or one or more alloys of which in powder form and contains a substance that emits gaseous nitrogen when in is hot, so that the nitride of this metal can form in the deposited metal. Some of this metal nitride is deposited as a fine, solid phase in the metal part during the Welding or deposited during a subsequent heat treatment, creating a tough, strong Weld deposit is achieved.

An inert gas such as argon, helium, a mixture of argon or Helium with oxygen or carbon dioxide, carbon dioxide or a mixture of carbon dioxide and Oxygen can be used.

Aluminum, inert gas arc welding processes can be used as nitride-forming metals

Applicant:

Yawata Iron & Steel Company, Ltd., Tokyo

Representative:

Dr. F. Zumstein,

Dipl.-Chem. Dr. rer. nat. E. Assmann

and Dipl.-Chem. Dr. R. Koenigsberger,

Patent Attorneys, Munich 2, Bräuhausstr. 4th

Named as inventor:
Sadayoshi Morita,
Teiji Ito,
Takeshi Nishi,
Tsuguro Kikuno, Tokyo

Claimed priority:

Japan December 29, 1961 (48 065)

Titanium, zirconium, beryllium, columbium, vanadium and alloys thereof, alone or in admixture, are used will.

Manganese nitride, calcium nitride, molybdenum nitride, chromium nitride and nitrates such as Ca (NO ₃ ) ₂ can be used as substances which release nitrogen when hot.

In the case of the arc welding according to the invention, any conventional powdery flux can also be used can be used for the protective gas, so that the weldability can be further increased.

The core of the welding wire, which is used according to the invention, can also be conventional Alloying elements, such as nickel, molybdenum and chromium, are added to the properties to further improve the weld.

The welding process is carried out in the same way as a normal inert gas welding. However, it is preferred to determine the content of metal

609 503/313

^to keep the deposited metal nitride practically within a range from 0.01 to 1.00%. During welding, the nitride-forming metal or alloy contained in the welding wire is melted together with the welding wire by the heat of the arc and forms a molten weld pool together with the material to be melted, which is made molten at the same time. Since dissolved nitrogen is dissolved in the molten bath by the protective gas or by the nitrogen-releasing substances, such as manganese nitride, the nitride-forming metal or the nitride-forming alloy forms a nitride as the bath melts together. Furthermore, under the influence of a subsequent heat treatment or the heat of the molten bath itself, part of this nitride is deposited in fine form in the solid phase. Therefore, the deposited metal has a fine structure and is high in toughness and strength.

The following examples serve to explain the invention in more detail without restricting it. In Examples 1 to 3, three welding wires are used which have the following composition:

Table 1
Chemical composition of the welding electrodes (core)

Sweat
electrodes C. Si Mn E.
P. elements in °
S. Cu Al Ti Fe A.
B.
C. 0.15
0.13
0.12 0.368
0.364
0.68 1.34
1.32
1.80 0.035
0.034
0.010 0.024
0.024
0.007 0.194
0.215
0.150 0.55
0.34 0.52
0.23 rest
rest
rest Example 1 1

A low-carbon, killed steel for as little as 4% nitrogen to the protective gas from carbon dioxide Temperatures was welded with a single welding 25 and thereby the protective gas at one speed fed at 251 per minute. The chemical composition of the welds was

using each of welding electrodes A, B and C having the chemi shown in Table 1

chemical compositions and admixing as shown in Table 2.

Tabel

Chemical composition of a single welding pad with a carbon dioxide-nitrogen protective gas was made on a low carbon killed steel

Sweat
electrodes C. Si Mn Elemei
Al ite in 7o
AlN J Ti 0.14
0.05. TiN Fe A.
B.
C. 0.10
0.10
0.08 0.26
0.24
0.48 1.08
1.10
1.41 0.16
0.11 0.043
0.030 0.089
0.081 rest
rest
rest

For comparison, it should be noted that when welding steel with a single welding pad under Using an arc with carbon dioxide as the shielding gas and an ordinary low-carbon one, silicon- and manganese-containing electrode pores were obtained when about 4% nitrogen was mixed with the Carbon dioxide protective gas were mixed. However, when using electrode wire A from Table 1, containing 0.55% aluminum, it was found that no pores were formed if up to 8% Nitrogen were mixed with the protective gas. Similar results were found in arc welding with argon as the shielding gas and a welding wire that does not contain aluminum, even with only 1% nitrogen in the protective gas, generates pores. However, when the welding wire A of Table 1 containing 0.55% aluminum was used, no pores were created until 4% nitrogen was present in the protective gas. If an electrode was used that contained titanium, which was higher Has affinity for nitrogen than aluminum, then it was possible to control the amount of nitrogen at which no pores were created to increase. For example, they were exposed to carbon dioxide during arc welding as a protective gas with the welding wire B of Table 2, which contained 0.52% titanium, even if Up to 12% nitrogen was added to the carbon dioxide, no pores detectable. It can therefore be seen that that the bond of nitrogen to a nitride-forming element, for example aluminum or Titanium, is effective in preventing the formation of pores when gaseous nitrogen is added to the protective gas is admixed.

The steels of the welds with the chemical compositions as shown in Table 2, run-after air-cooling of 900 ⁰ C and a weld which, however mitKohlendioxyd was prepared as a protective gas, using the electrode C only had the following mechanical properties:

Tabel

Mechanical properties of a single-line arc welding, weapons manufactured using carbon dioxide and nitrogen as a protective gas

tensile strenght Yield point strain Cross-sectional
reduction Beats
mkg strength,
/ cm ² Chärpy examination
with V ^ notch
VTrI 5 VTrs ° C kg / mm ² kg / mm ² ° / o ° / o -6O ⁰ C Ö ° C ⁰ C <-60 A. 59.6 50.1 36 _S 7 69.0 9.0 20.3 <-60 <-60 B. 62.7 56.1 34 _§ 5 66.3 11.1 22.2 <-60 <-60 C. 68.3 58.8 33.0 65.7 9.9 22.6 <-60 -10 C. 61.8 53.2 30.1 62.6 1.1 19.1 -46

The electrodes C and C have the same chemical composition. In the table, however, a distinction is made between C and C, because C is the mechanical properties when using this electrode and using carbon dioxide-nitrogen indicates the protective gas, while in line C the mechanical properties when using the same electrode core, but are given using carbon dioxide as the protective gas alone.

When comparing with the weld that is generated below 20 at which nitride in the weld,

Use of carbon dioxide alone as protective gas is remarkable. On microscopic examination

for the arc was made, the reinforcements are the steel the weld was found to be

the notch toughness due to the process, a very fine structure had developed.

Example 2

A multilayer weld was made, with the metal of the welds and the metal one

each of the welding wires A, B and C to the arc welding point, that with a welding wire C and only

welding under carbon dioxide - nitrogen as protective - carbon dioxide as protective gas was produced

gas was used. The mechanical properties 30 as follows:

Tabel

Mechanical properties of a multi-layer weld produced by means of an electric arc and carbon dioxide - nitrogen as a protective gas

tensile strenght Yield point strain V4 UCi al / JUULL Ho "
reduction Impact resistance, / ciö ² Charpy examination score
VTfs kg / mm ² kg / mm ² ° / o ° / o mkg 0 ⁰ C with V-
VTrIS ° C 60.2 51.0 35.2 67.9 -6O ⁰ C 18.5 ° C <-60 A. 64.1 57.9 33.3 66.8 6.8 19.2 <-60 <-60 B. 67.8 57.8 32.9 63.4 9.4 19.6 <-60 <-60 C. 64.7 54.9 28.5 60.3 7.6 11.2 <-60 -18 C. 1.8 -50

C means the mechanical properties when using the same electrode C, but using argon alone as protective gas.

The mechanical properties of the steel of the weld are the result of the same welding process, as used in Example 1, and the heat treatment caused by the heat of the Arc was caused, which was used to form the next layer of the weld. This steel has excellent mechanical properties because it has a normalizing effect because of the Heat of the layers formed on top of one another. With such a weld were the mechanical properties of a weld produced by means of an arc in which no nitrogen was mixed with the protective gas, worse.

SS Multi-layer welding was performed, with each of welding wires A, B and C in Table 1 used, but 4% nitrogen in argon was used as protective gas and this with a lot of 25 liters per minute was added. The mechanical properties of the welds are given in Table 5 reproduced, the weld C with the welding wire C and pure argon as protective gas was made. The mechanical properties of these welds were as in the above Example 2, excellent and superior to the welds made without nitrogen admixture in the protective gas were manufactured.

Tabel

Mechanical properties of multi-layer welds made with argon-nitrogen as a shielding gas using the arc process

tensile strenght Yield point strain reduction Impact resistance, / cm ² Charpy examination ° C kg / mm ² kg / mm ² ° / o % mkg 0 ° C with V-notch
VTrI 5 VTrs <-60 63.4 55.2 37.1 68.3 -60 ° C 25.9 ° C <-60 A. 66.7 58.8 36.0 67.1 10.2 25.4 <-60 <-60 B. 72.0 63.9 34.5 66.8 13.7 23.8 <-60 <-60 C. 69.1 60.5 26.4 61.3 11.4 14.5 <-60 C. 3.8 <-60

C means that only ordinary argon was used as protective gas.

B ice pi

A core electrode was made by inserting a hollow core with an outer diameter of 3.2 mm, which was formed by bending a very soft steel sheet; filled with a powder that through Mixing 0.5% aluminum, 0.3% titanium and manganese nitride in sufficient quantities to form the Nitrides of aluminum and titanium through nitrogen evolution, together with ferrosilicon and ferrous

el 4 manganese as a deoxidizer and a flux to improve workability. A single layer weld and a multi-layer weld were produced by means of an inert gas arc. Carbon dioxide alone was used as the protective gas with, fed at an amount of 201 per minute. The chemical compositions and mechanical Properties of the welds are given in Table 6.

Tabel

Chemical compositions (in percent) and mechanical properties of the welds that were made using a specially designed hollow core

C. Si Mn Al Ti AlN TiN Fe Single layer welding 0.08
0.11 0.35
0.42 1.27
1.36 0.13
0.22 0.06
0.10 0.037
0.032 0.062
0.068 rest
rest Multi-layer welding

Tensile strength kg / mm ²

Yield point

kg / mm ²

Elongation reduction in cross-section

Impact resistance,

mkg / cm ² -6O ⁰ C 0 ° C

Charpy examination

VTr 15

Single layer welding
Multi-layer welding ...

63.5 67.2

54.7 59.1

60.4
58.2

7.6
5.4

17.4 18.3

<-60 <-60

It can be seen that the same effect as produced in Examples 1 and 2 with a Arc is achieved under carbon dioxide as a protective gas and a hollow core as welding wire, which Contains nitride-forming elements and a nitrogen-releasing compound.

Claims (17)

Patent claims: 1. A method for gas-shielded arc welding of steel, characterized in that that in addition to the usual welding consumables, a nitride-forming metal and brings nitrogen to the welding point during welding, so that the nitrogen with the Metal forms nitride, which is at least partially finely distributed in the solid phase deposited in the weld metal will. 2. The method according to claim 1, characterized in that the nitride-forming metal is aluminum, Titanium, zirconium, beryllium, columbium, vanadium and alloys of these metals, alone or in Mixture, can be used. 3. The method according to claim 1, characterized in that in a known manner Nitrogen is fed to the weld with the shielding gas. 4. The method according to claim 1, characterized in that the nitrogen of the weld through a consumable electrode is fed, the components of which are nitrogen when heated deliver. 5. Electrode according to claim 4, characterized in that the nitrogen supplying material Manganese nitride, calcium nitride, molybdenum nitride, chromium nitride, alone or in a mixture, and / or the nitrates of the aforementioned metals can be used. 6. The method according to claim 1, characterized in that in a known manner nitride-forming metal is fed to the welding point through your consumable electrode. 7. Electrode according to claim 6, characterized in that the core wire is 0.55% aluminum contains. 8. Electrode according to claim 6, characterized in that the core wire contains 0.52% titanium. 9. Electrode according to claim 6, characterized in that the core wire 0.34% aluminum and contains 0.23% titanium. 10. Electrode according to claim 6, characterized in that the electrode core consists of a powder Contains aluminum, titanium and manganese nitride. 11. Electrode according to claim 6, characterized in that it is aluminum as the nitride-forming metal, Titanium, zirconium, beryllium, niobium and / or vanadium and / or alloys of these metals contains. 12. Electrode according to claim 6, characterized in that it is substantially weight after of 0.15% C, 0.368% Si, 1.34% Mn, 0.035% P, 0.024% S, 0.194% Cu, 0.55% Al and the remainder consists of iron. 13. Electrode according to claim 6, characterized in that it is substantially weight after of 0.13% C, 0.364% Si, 1.32% Mn, 0.034% P, 0.024% S, 0.215% Cu, 0.52% Ti and the remainder consists of iron. 14. Electrode according to claim 6, characterized in that it is essentially by weight of 0.12% C, 0.68% Si, 1.80% Mn, 0.010% P, 0.007% S, 0.150% Cu, 0.34% Al, 0.23% Ti and the remainder consists of iron. 15. Electrode according to claims 4 and 6, characterized in that the electrode core ίο contains as nitride-forming metal Al, Ti, Zr, Be, Nb and / or V or their alloys and a material that gives off nitrogen when heated, this material being manganese nitride, calcium nitride, Molybdenum nitride and / or chromium nitride or igen is nitrate. 16. Electrode according to claim 15, characterized in that it is essentially the Weight after of 0.08% C, 0.35% Si, 1.27% Mn, 0.13% Al, 0.06% Ti, 0.037% AlN, 0.062% TiN and the remainder consists of iron. 17. Electrode according to claim 15, characterized in that it is essentially the Weight after of 0.11% C, 0.42% Si, 1.36% Mn, 0.22% Al, 0.10% Ti, 0.032% AlN, 0.068% TiN and the remainder consists of iron. Considered publications:
see German Patent No. 496 337; Austrian Patent No. 174 268;
U.S. Patents Nos. 2,142,045, 2,851,581,
988 627; William M. Conn, The Technical Physics of Arc Welding, Berlin-Munich, 1959, p. 211/212; T. N ο r e n, materials science for the arc welding of iron and steel, Solingen, 1955, p. 37; K. L. Zeyen and W. Lohmann, welding der Eisenwerkstoffe, Düsseldorf, 1948, pp. 75 to 77. 609 503/313 1.66 1.66 © Bundesdruckerei Berlin