DE1227666B - Chromium-alloyed free cutting steel - Google Patents

Description

Chromium-alloyed free cutting steel The invention relates to -a chromium-alloyed steel, which has good properties in terms of special additives machining by cutting tools. Such steels are referred to as free cutting steel.

By the French patent 1219 601 is already a free cutting steel known, the low or medium carbon content and customary for this Manganese, silicon, phosphorus, sulfur and nitrogen contents 0.02 to 0.5, l / @ contains lead and tellurium, the remainder iron with the usual melting-related Impurities.

The invention has set itself the task of the mechanical and physical properties of such steels while maintaining their good To improve machinability, especially in terms of tensile strength and hardenability. The generally known prior art offers itself as an alloying element chromium for this purpose, but is according to the knowledge on which the invention is based an addition of chrome to the well-known free-cutting steels, which lead and tellurium have in common included, not easily and not within any limits suitable to a Improvement of the mechanical strength properties without impairing the allow good machinability.

In the presence of tellurium in a lead-containing steel it has been shown that that tellurium is preferably present in connection with lead as inclusions, in the form of lead-tellurium compounds, but nowhere with manganese or Iron connects, with the possibility that the excess tellurium in solid solution is contained in the steel structure. All the lead, however, lies with the Tellurium as lead-tellurium inclusions, which improve the machinability of the steel.

The lead-tellurium inclusions do not only consist of lead and lead telluride, but also contain other intermetallic compounds of tellurium and lead, the typical lubricating effect of lead inclusions and short chip formation cause.

The manganese sulphide inclusions present in the steel are normally in the as-cast state and the lead-tellurium inclusions are spherical in shape, but are hot-worked the manganese sulfide inclusions stretched so that they assume an ellipsoidal shape. In contrast, the lead-tellurium inclusions take the form of flat veins that are in the run essentially parallel to the rolling direction.

To significantly improve the machinability of a lead and To achieve tellurium containing steel, it is necessary that the lead-tellurium inclusions are evenly distributed in the steel and not as islands or large spheres Inclusions are present. This even distribution is essential for every machining process necessary in which the cutting edge of the tool is transverse to the longitudinal direction of an elongated rolled steel body runs. This results in such a uniform distribution of lead-tellurium inclusions, the probability is significantly greater, purely statistically, that the tool hits one of the inclusions. Furthermore guarantees a such even distribution of lead-tellurium inclusions that the physical and mechanical properties of the steel are not caused by irregular accumulations be affected by inclusions.

In a simple carbon steel there are lead-tellurium inclusions evenly distributed throughout the steel. However, if lead and tellurium in chromium alloy There are steels with more than a certain amount of chromium, the chromium has a serious adverse effect on the distribution of lead-tellurium inclusions the end. It causes the lead-tellurium inclusions in previously mentioned large spherical-like There are accumulations. This results in the need for chromium-alloyed Steels containing both lead and tellurium to improve machinability, the amount of chromium must be precisely limited in order to ensure an even and wide distribution of inclusions to achieve good machinability as also to ensure that good physical and mechanical properties are achieved.

Another essential part of the present invention is that the steel should have good hot working properties. For such good ones To ensure hot working properties is a careful control of the manganese content also necessary to ensure that no hot fracture occurs.

The chromium alloy free cutting steel according to the invention has the following Composition: 0.5 to 1% carbon, 0.6 to 1.6511 / o manganese, 0.02 to each 0.05% lead and tellurium, 0.18 to 5% chromium, up to 0.3% silicon, the remainder iron and Impurities of sulfur, phosphorus and nitrogen caused by the melting process Importance of careful control of the chromium content within the range of 0.18 to 5119 is explained in more detail below with reference to drawings. It shows F i g. 1 is a photograph enlarged 500 times of the structure of a containing ordinary lead and tellurium. Carbon steel, Fig. 2 an 'x-ray in 100-fold magnification of a 0.07.62 mm thick steel sample according to FIG. 1, FIG. 3 is a photomicrograph - magnified 500 times - of another ordinary one Carbon steel containing both lead and tellurium, in the as-cast condition F i g. 4th a photomicrograph, again magnified 500 times, of an as-cast one Stole it; which has the same composition as that of FIG. 3, but additionally has a chromium content of 10 to 13 a / o-, F i g. 5 is another photomicrograph of the steel according to FIG. 4 with the same magnification and FIG. 6 another photomicrograph, also in 500-fold enlargement of a steel of the same composition of F i g. 3, again - in the as-cast state, the steel in this example containing 5% chromium.

As the F i g. 1 and 2 of the drawings include the common one Carbon steel elongated vein-like lead-tellurium inclusions, the lead-tellurium inclusions in Fig. 1 dark and in FIG. 2 appear bright. The manganese sulphide inclusions, which are present in spherical or lenticular inclusions appear in F i g. 1 bright and in FIG. 2 dark. From these two figures the broad and even distribution of the inclusions over the entire steel body was observed will.

The representation of FIG. 3 underlying steel has the following composition: C ............ '........ 0.10% Mn. . . . . . . . . . . . . . . . . . . . 0.60 to 0.90% P ...................... 0.010 / 0 S ...................... 0.023% Se. . . . . . . . . . . . . . . . . . . . . 0.08% maximum Pb. . . . . . . . . . . . . . . . . . . . . 0.015 to 0.250 / 0 Te. . . . . . . . . . . . . . . . . . . . 0.03 to 0.04% The dark spots on the background in Fig. 3 are the lead-tellurium inclusions. These inclusions are distributed evenly and far apart over the entire structure. The F i g. 4 and 5, on the other hand, show a steel in the as-cast state which has the same composition as the steel according to FIG. 3, but additionally contains 10 to 13% chromium. In the photomicrograph of the FIG. 4 it can be seen that the lead-tellurium inclusions (dark spheres) are agglomerated into individual, relatively locally concentrated collections. In the case of FIG. However, FIG. 5, which shows a photomicrograph of the same steel, results when compared with FIG. 3 that this steel does not contain any lead-tellurium inclusions which improve the machinability.

The effect of the presence of chromium with a content within the The range between 10 and 13.1 / o thus leads to the lead-tellurium inclusions very unevenly distributed. Instead of improving workability within the total amount of steel, this is not achieved, but limited only on a locally limited improved machinability. This locally concentrated, relatively large lead-tellurium inclusions impair Because of their relatively large expansion (see Fig. 4), the mechanical Properties of steel are more serious than - in other matching steels -, which do not contain lead and tellurium together.

F i g. 6 is a photomicrograph at the same magnification as F i G. 3 to 5 (500 times) of the same steel as in FIG. 3, which is also in the cast iron is present, but has a chromium content of only 5%. The distribution and the Size of the lead-tellurium inclusions, namely the dark spots on the light background, are not as evenly distributed as in the case of chrome-free steel from F i g. 3; however, the inclusions are spaced apart and less clumped together, than is the case with the lead-tellurium inclusions in the 10 to 13% chromium containing Steel according to FIGS. 4 and 5 can be determined. Forms a chromium content of 5% thus the upper limit at which the distribution of lead-tellurium inclusions can be felt begins to be impaired. Therefore, according to the invention in chromium-alloyed Steels in which the machinability is improved by lead and tellurium together should be, the maximum value is a chromium content of less than, d. H. just 5% elected. The lower limit of 0.18% chromium was chosen because this amount is still noticeable affects mechanical and physical properties of the steel. It has showed that chromium alloy steels with a chromium content lower than 0.18% are common Carbon steels are comparable. Because such a low chromium content affects the distribution of lead-tellurium inclusions does not.

The minimum lead and tellurium contents are in the case of the invention Steel 0.02%. These levels are required to be noticeable and usable Improvement of the machinability of the steel compared to otherwise matching To achieve steels which do not contain one or both of the elements mentioned. The highest lead content is set at 0.5% because the steel then when its lead content exceeds this limit, is felt in terms of its mechanical and physical Properties deteriorated. The greatest tellurium content of 0.51 / o is due to the Determined hot brittleness of steel at red-hot rolling temperature. A tellurium content of more than 0.511o would do so lead to larger ones during hot rolling Cracks would appear. An increase in the temperature range at which the steel can be hot rolled, or an increase in the ratio of manganese to sulfur the hot brittleness caused by a tellurium content of more than 0.5 0 / a not sufficiently compensate.

In a preferred embodiment of the steel according to the invention, the tellurium content from 0.04 to 0.20 0/0. It has been found that at the present of tellurium within this range along with a lead content of approximately 0.20 to 0.30% an ideal increase in machinability occurs.

As already explained, a tellurium can be used together with lead containing Steel due to the presence of tellurium have a property called hot brittleness referred to as. This unfavorable property results from an excess of Tellurium in solid solution in the structure at hot rolling temperature. About the risk of warm brittleness to reduce, the magnesium content of the steel according to the invention should not be smaller than 0.6%.

In another preferred embodiment of the invention, the sulfur content of the steel between 0.02 and 0.5% to the machinability of the Steel continues to be made of magnesium sulfide inclusions, which in a well-known way increases the machinability improve, enlarge. Because of the adverse effect that sulfur has on steels in that it also leads to warm brittleness, can, as before mentioned, the magnesium content can be increased to 1.651 / o.

The carbon content of the steel according to the invention is in the range between 0.05 and 10/0, and other elements commonly found in steels as impurities are present, such as B. phosphorus, nitrogen, can also be used in small amounts to be available. Silicon, which is normally found in chromium-alloyed steels should not exceed 0.3% in order not to be machinable to affect.

The chromium-alloyed steel according to the invention can also contain small amounts other alloy components, such as B. nickel, molybdenum or vanadium, in quantities, which are not large enough to classify the steel from the category of non-stainless steels to highlight included.

The chromium-alloyed free-cutting steel according to the invention is a Free cutting steel is created that has all the physical and mechanical properties of a chromium alloy steel that are better than that in many respects ordinary carbon steel, such as B. increased tensile strength and good Hardenability, which is of great importance for many types of use.

Claims (3)

Claims: 1. Chromium-alloyed free-cutting steel, consisting of 0.05 up to 1% carbon, 0.6 to 1.65% manganese, 0.02 to 0.5% each of lead and tellurium, 0.18 to 5% chromium, up to 0.3% silicon, the remainder iron and impurities from the melting process of sulfur, phosphorus and nitrogen. 2. Chromium-alloyed free cutting steel according to claim 1, the tellurium content being 0.04 to 0.2%. 3. Chromium-alloyed free cutting steel according to claim 1 and 2, wherein the sulfur content is 0.02 to 0.5%. Into consideration Drawn pamphlets: French patent specification No. 1219 601.