DE1153045B - Process for the simultaneous annealing and decarburization of cold-worked silicon steel - Google Patents

Description

The invention relates to a method for the simultaneous soft annealing and decarburization of cold-worked material Silicon steel with 1 to 4% silicon and a maximum of 0.05% carbon, preferably 0.02 to 0.03% carbon.

It is generally known that the lower its carbon content, the better the magnetic properties of a steel. The carbon content of silicon steel ingots, which are used as a starting material for the production of steel strip for electrical purposes, is a maximum of 0.05% and normally has a value of 0.02 to 0.03 ⁰ Zc. However, the maximum permissible carbon content is given today with about 0.006% with regard to low magnetic losses. Recent work has shown that the carbon content of magnetic sheets must be below 0.002% if an age-related increase in magnetic losses in transformers is to be avoided. The carbon content of the starting material must therefore be further reduced by appropriate processing methods.

In the known manufacturing method for silicon steel of the type mentioned above, the ingot rolled out and annealed to remove unwanted contamination and stress. The rolled material is usually subjected to a heat treatment at around 950 ° C, to soften the steel strip to facilitate later rolling and the existing ones Eliminate tension. Usually the steel strip is used after having the desired Starch obtained in a de-carbonating atmosphere at a temperature of about 800 ° C decarburized.

It has also been proposed to use annealing and decarburizing to improve magnetic properties of steels in a humid hydrogen atmosphere in a single Process step.

The present invention is based on the object of a processing method for silicon steel indicate, by means of which the carbon content in the end product is reduced to an even lower level than previously achievable Value comes to rest.

According to the present invention, this is achieved in that the cold-worked silicon steel its surface is first degreased and made metallic bright and then at 875 bis 1025 ° C for up to 10 minutes in moist, pure neutral gas with a dew point from minde process for simultaneous soft annealing

and decarburization of cold worked

Silicon steel

Applicant:

General Electric Company,
Schenectady, NY (V. St. A.)

Representative:

Dr.-Ing. M. Licht, Munich 2, Sendlinger Str. 55,

and Dr. R. Schmidt, Oppenau (Renchtal),

Patent attorneys

Claimed priority:
V. St. v. America November 15, 1957 (No. 696 616)

Elmore Joseph Fitz, Lanesboro, Mass. (V. St. A.),
has been named as the inventor

at least -40 ° C, preferably above 2 ° C, annealed will.

The most varied types of reducing and oxidizing atmospheres are for the earlier process has been used for carbon removal, but the gases previously used have so far not proven to be completely satisfactory as in some cases the carbon content achieved is not sufficiently small, the time required for adequate carbon removal was too long, and the the results obtained were not consistent; or other reasons made them appear inadequate.

Some of the atmospheres previously used contained oxygen or hydrogen. In connection with the invention it has been discovered that in fact the presence of both oxygen and of hydrogen in the de-carbonizing atmosphere results in effective carbon removal from the steel, d. H. except for a very small percentage, to prevent what is contrary to the lessons of the previous procedure. In other cases there were other gases, ζ. Β.

Carbon dioxide, contained in the de-carbonating atmosphere; but also the carbonaceous ones Gases have the achievement of an extremely low

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Carbon content is prevented, likely to be on. Since the optimal temperature range for the Reason for stress relief annealing between the carbonaceous gas at around 925 to 955 ° C and the equilibrium entering steel that lies, the procedure given here is outside of one further withdrawal of the carbon foiled, properly suited, simultaneously with the desobald the equilibrium state has been reached 5 stress annealing during the machining of the was. Silicon steel to be carried out. The at arrival

It seems that the twist of this method carried out according to the invention for a maximum

Carbon removal mainly from moisture Carbon removal time required is maximum

of the gas mixture present is effected and that at least 10 minutes.

the gas or gases per se are only used for veri o A number of experiments were carried out

serve to thin the water vapor and neutralize the effect of the various known

to compare the atmosphere of the metal and its constituents with that of the invention,

have to. In the course of these experiments, groups of

It is therefore of particular importance for the ten samples of the same silicon strip from the invention that reacting gases, e.g. B. oxygen and 15 3.5 cm thickness first cleaned, ie in an acidic hydrogen, or carbon-containing gases, such as solution pickled, degreased and washed. Post-carbon dioxide, to be avoided entirely and that, following that, each sample was subjected to a pure, neutral, heat treatment for 10 minutes for this purpose. Any group of thinning gas. z. B. Nitrogen was used as the carrier for the ten samples in another of the four types of carbon-removing water vapor. Treated during 20 atmospheres. These 4 atmospheres of nitrogen being a particularly suitable neutral were the following: (a) Line nitrogen is 0.2 gas, just from economical to 0.3 ¹⁰ Zo oxygen; (b) pure nitrogen (from a line standpoint, if desired, deoxygenated nitrogen can be used); also other neutral gases such as argon, helium, (c) air; (d) essentially pure hydrogen. In krypton, neon, and the like, or mixtures of these gases 25 in each of the aforementioned atmospheres, water vapor would be used in its place. introduced; the dew point was 26 to 29 ° C.

The ratio of water vapor to the usable was also added another group of ten

th nitrogen or a corresponding gas is samples that are not in the manner described above

not decisive in the invention, since one had been cleaned firmly beforehand, at the same temperature

found the same results with respect to 30 temperature in a moist, pure nitrogen atmosphere

Carbon removal can be achieved when using the moisture content specified above

Atmosphere is saturated with moisture or when heat-treated.

They only have a relatively low moisture content. Analysis of the carbon content of these samples

has a share of the workforce. It is Z. B. a successful showed after carbon removal treatment

Carbon removal at a dew point of only 35 the averages listed below for

-40 ° C. However, it is prior to those treated in the atmospheres mentioned

to work with dew points above 2 ° C, samples:
as the process is then less sensitive to small differences in the surface atmosphere

treatment is. Increasing the dew point to 40

Temperatures above 2 ° C increase the effectiveness

of the process does not, but offers the practical tap nitrogen.

Advantage that the desired water vapor is in the air

pure neutral gas in the following manner- tap hydrogen can be set: You pass the pure neutral 45 pure nitrogen ..

Carbon content

0.002% 0.003% 0.014% 0.001%

Gas through a water bath at room temperature,

d. H. at 21 to 29 ° C. The additional samples that were not previously

It is important to make sure that the cleans and that of a clean, damp nitrogen steel surface had been subjected to coal atmosphere prior to treatment had one Substance withdrawal is thoroughly cleaned; especially must 50 carbon content of 0.003%. all scale removed from the previous warm A carbon content of less than 0.002% rolling can be eliminated. can only be done with today's analysis methods To this end, the steel can be blown off or difficult to pinpoint, and so there is in an acidic solution, e.g., a mixture, there is good reason to believe that the Hydrogen chloride and hydrofluoric acid, 55 percent for those samples which are in the pure, stains and then washed in water. The humid nitrogen atmosphere of the invention is purifying Must be thorough, so that a clean, act was well below the stated value bare metal surface on the steel is created. of 0.001%. Nine out of the ten tested All traces of fat are also said to have been removed from the surface what with HiKe's well-known steam content of 0.001% and one of 0.002%. the degreasers before introducing the carbon removal results with the previously cleaned and chambered can be reached. according to the invention in pure, moist nitrogen

Using the method of the invention, treated samples obtained showed a

the carbon removal in a temperature range is eighth improvement compared to those that

from 875 to 1025 ° C carried out effectively. 65 used in the others for carbon removal

This fact is in contrast to the earlier atmospheres achieved. That achieved

Procedure that taught that the best carbon reduction in magnetic aging loss

Removal of substances achieved at temperatures below 875 ° C makes the silicon steel the significant practical

Value of the procedure described. This fact is of particular importance because it is experimental it has been proven that magnetic aging is considerable at a carbon content of more than 0.002% increases.

The results of the tests described above also show that the remaining on the samples Scale significantly interferes with carbon removal when treating such samples to be subjected to carbon removal, and that therefore the removal of scale and other impurities by the previous cleaning described the maximum carbon removal from the Steel promotes a lot.

One method that may be considered an embodiment of the invention is a silicon steel ingot with about 3% silicon and 0.02% carbon first to a thickness of about 2.16 cm hot rolled and cold rolled after removing scale and other contaminants to a thickness of about 0.07 cm. The steel strip is then subjected to stress relief annealing at the same time with the carbon removal treatment at temperatures between 925 and 955 ° C for 4 minutes long subject. The low-carbon steel strip is then reduced to a thickness of 0.03 to 0.04 cm cold rolled. The steel produced in this way can be refined using the known processes and structural improvement are subjected.

With the procedure outlined above, cleaning can be carried out immediately after hot rolling happen as described, or it can be done at the same time with the up immediately before Carbon removal processes taking place in the stress relief annealing are postponed.

With the aid of the invention, silicon strip can be produced with a minimum of detectable carbon getting produced. It can be made by applying a heat treatment to remove carbon, which allows a relatively wide temperature range, if one considers the earlier to be optimal Temperatures considered for the greatest possible carbon removal are used for comparison. from A particular advantage is the combination of carbon removal with stress relief annealing while using it temperatures well over 900 ° C, which is the optimal range for annealing. on In this way, the previously final process of carbon removal is omitted. In addition, the Carbon content reduced more than by any of the conventional methods in the same Time was achievable.

Claims (3)

PATENT CLAIMS: 1. A method for the simultaneous soft annealing and decarburization of cold-worked silicon steel with 1 to 4% silicon and a maximum of 0.05% carbon, preferably 0.02 to 0.03% carbon, characterized in that the surface of the annealing material is first degreased and made metallic bright and the material is then annealed at 875 to 1025 ° C for up to 10 minutes in moist, pure, neutral gas with a dew point of at least -40 ° C, preferably above 2 ° C. 2. The method according to claim 1, characterized in that the annealing at a temperature from 925 to 955 ° C in a humid nitrogen atmosphere. 3. The method according to claim 1 or 2, characterized in that the annealing material before the annealing treatment first rolled out to an intermediate thickness while warm, then cleaned and then further rolled out in the cold state and in the cold after the annealing treatment Condition is rolled out to the final thickness. Considered publications:
German Patent Nos. 884 813, 931661;
U.S. Patent No. 2,765,246;
Excerpts from German patent applications, Vol. 19 (1948), p. 160; (H 175140 VIa / 18c). © 309 668/234 8.