DE1458424C - Use of a steel for the manufacture of surface-hardened cold rolls - Google Patents

Description

The invention relates to the use of a steel as a material for the production of surface-hardened steel Cold rolling.

Steels of this type are known per se. They usually contain from 0.60 to 1.30 ° / ₀ carbon to be sufficiently cured by heating for A3 and then quenching. To improve the hardening depth, it is known to add nickel, molybdenum, tungsten and vanadium to the alloys. Silicon and manganese contamination caused by the melting process is also permitted.

For the production of dimensionally stable tools, such as thread cutters, screw taps, caliber tools, cold dies, etc., it is known from German Patent 559 074 to use steels with 0.9 to 1.0% carbon, the cobalt content between 0.2 and 5.0 ° / ₀ . In addition, these steels can be alloyed with small amounts of manganese, tungsten, chromium, vanadium and others. The mentioned Co contents lead to a high dimensional stability during hardening, which is of particular importance for the mentioned precision tools.

For the production of hot rolls, US Pat. No. 2,053,346 discloses steels with up to 4% carbon, 0.40 to 1.25% cobalt, 0.25 to 2.0% chromium, 0.7 to 1.0 ° / ₀ manganese, 0.15 / to use to 1.25 ° ₀ silicon, balance iron. The rolls made from these steels should be particularly resistant to thermal shock, such as inevitably occur during hot rolling.

Corresponding to the nature of the cold rolling process the previously known steels are not readily suitable for the production of cold rolling. The cold rolling treatment of metals is known to have the purpose of smoothing the surface of the rolling stock and to condense as possible. Accordingly, the aim is to use the highest possible rolling pressures. Experience has shown that it is often unavoidable here that misrolling occurs insofar as when relative movements occur between the surfaces of the rolling stock and the roll barrel, whereby the surfaces are heated to high temperatures in a relatively short time. the The consequence of this is that the hardened surface layer of the roll undergoes a brief tempering treatment is subjected to high temperatures, whereby its hardness decreases. This is what happens with the well-known Steel easily cracks, causing the surface of the roll, but sometimes also the entire roll barrel gets destroyed.

. In this prior art, the objective is to propose a steel for the production of cold rolls which, in addition to good hardenability and high hardenability, has the highest possible crack resistance with localized heating to high temperatures.

This object is achieved according to the invention in that a steel is used for the production of cold roll barrels

up to 2.0%
up to 2.0%
up to 2.0%
up to 2.0%

nickel
molybdenum
Vanadium
tungsten
Remainder iron

up to 1.30% carbon 0.25 to 3.50% silicon <Q, I5 to 1.60% manganese
Iß® up to 3.50 % chromium 0.30 to 8.00% cobalt

as well as, if applicable

is used as a material with impurities caused by the melting process.

The specified carbon contents are required to make the steel sufficiently hardenable. For the stated purpose, you must Surface hardnesses of over 760 Vickers units (hereinafter abbreviated to HV) can be achieved. If the coals material content is outside this range, such hardnesses cannot be achieved.

The two elements manganese and nickel are suitable for improving hardenability. But with that As the manganese and nickel content increases and the retained austenite content increases, these elements have to go up 1.6% manganese or 2.0% nickel must be limited. The addition of molybdenum improves the hardenability of the Steel and also suppresses the retained austenite to a certain extent, which makes it suitable for the proposed purpose is promoted. In addition, Mo increases the fineness and the even distribution of carbide precipitates.

Molybdenum, vanadium and tungsten also form very hard carbides. The addition of these elements therefore improves the abrasion resistance of the steels. The addition of these metals in other than this However, the alloy composition described has the effect that the sensitivity to crack formation increases, especially with localized sudden increases in temperature.

The cause of these undesirable cracks volume contraction is considered, which is caused by carbide precipitation in the martensite microstructure at 250-520 ⁰ C. This volume contraction is also called secondary contraction.

According to the invention it was recognized that the secondary contraction in alloys of the type mentioned can be significantly reduced if cobalt is added to the alloys in amounts of 0.30 to 8.0% will. Of particular technical importance is the fact that this addition makes the hardenability of the steel is not deteriorated.

The hardenability comes together with the crack resistance and the achievable surface hardness in the manufacture of cold rolls is of particular importance. As mentioned earlier, surfaces are hardening of over 760 HV is required, whereby a hardening depth of at least 1.25 cm is required. Like the in The following reproduced test results can be seen, it is possible with the invention composite steels to meet these requirements.

The increase in resistance to cracking for locally hardened on passing warming roll surfaces is the greater, the higher the Co content is within the specified limits. On the other hand, it is not desirable to add too large an amount of Co , since this can cause disturbances in the hardening effect. In a further embodiment of the invention it is therefore proposed to eliminate the disadvantages of excessively high Co contents by adding silicon to the alloys in amounts of 0.5 to 3.5%. The amount of Co or Co + Si can vary depending on the desired hardness or the shape of the roller body

to be changed. As already mentioned, the composition can lie within the following limits:

Carbon 0.60 to 1.30%

, Cobalt 0.3 to 8.0%,

Silicon ...; 0.5 to 3.5%

The reasons for limiting the levels are as follows: Less than 0.60% carbon the required hardness of 760 HV is not achieved. If more than 1.30% carbon is used, the required Hardness depth not reliably preserved.

The relationships between the amount of cobalt and the crack resistance, as well as the thickness of the hardened Layer is from the drawing, F i g. 1 and 2, can be seen.

On the abscissa in FIG. The diagram shown in Fig. 1 shows the Co content in percent by weight and on the ordinate shows the Vickers hardness HV. If, in the event of rolling disturbances on the surface of the If abnormal heat build-up occurs, the surface of the bale is tempered, which causes the Hardness decreases. The higher the temperature generated, the more the hardness is lowered until the Roller breaks. The ordinate of FIG. 1 shows the hardness at which cracking occurs, i.e. i.e., the lower the hardness, the more resistant the roller is to sudden heating.

Curves 1 and 2 of FIG. 1 show that the cracks occur when the hardness is in the range below these curves. From Fig. 1 it can also be seen that the greater the Co content, the greater the resistance to cracking of the investigated steel alloys is improved.

Curve 1 of FIG. 1 corresponds to a steel with 0.67% C, 2.2% Cr, 0.26% Mo and 0.15% V.

Curve 2 corresponds to a steel with 1.5% C, 3.5% Cr, 0.35% Mo and 0.5% V. Fig. 1 shows that by increasing the Co content (in each case on the Abscissa plotted) the suppression of crack formation is promoted, i.e. the crack resistance increases. However, if there is more than 8% cobalt, the steel begins to lose hardness and becomes less resistant to thermal shock. There are also no further improvements in crack resistance achieved more. The maximum Co content according to the invention is 8%, the minimum at 0.3%. As can be seen from the drawing, there is no effect when the Co content is less than 0.2%.

F i g. 2 shows the influence of the Co content on the hardening depth, which in the present case was determined with the aid of the Forehead deterrent attempt has been determined. The numbers 0.10, 20, 30, 40, 50, plotted on the abscissa, 60 means the distance in millimeters from the hardened surface.

The in F i g. 2 curves correspond to the following steels:

F i g. 3 essentially corresponds to FIG. 1, but with the difference that on the abscissa the Si content is plotted in percent by weight. The ordinate shows the Vickers hardness achieved. Curve 1 corresponds to a steel with 0.66% C, 2.3% Cr, 0.30% Mo and 0.13% V. Curve 2 corresponds to one Steel with 1.18% C, 2.2% Cr, 0.31% Mo and 0.10% V. The respectively changed Si contents are on the abscissa applied. The diagram shows that although Si has a considerable influence on the crack resistance, if the amount is higher than 0.5% is, it must be higher than Si is generally found in steels of this type. But if the Si content is over 3.5%, it not only reduces the thermal conductivity and thermal shock resistance, but it also makes the resistance to cracking uncontrollable.

In a steel according to the present invention, the maximum amount of Si is 3.5%.

From Fig. 3 of the drawing it can also be seen that even with the addition of the same amount of Silicon to a general cold roll steel the crack resistance is improved. The reason seems to lie in the fact that silicon in the previously specified range of quantities together with a suitable Addition, e.g. B. 0.3 to 8.0% Co, not only improves the crack resistance wedge, but also the disadvantage compensates for the reduction in hardenability.

F i g. 4 shows the result of forehead quenching tests. It is the influence of silicon on those containing Co Steels visible. Each curve corresponds to a steel with the following composition:

35 ^curve 7oC 7oCr ⁰ UCo 7oSi 1
2
3 0.83
0.83
0.83 1.85
1.85
1.85 2.0
2.0
2.0 0.5
1.5
3.0

From the drawing it can be seen that the amount of silicon in the carbon, cobalt and chromium containing steel alloy improves the hardenability. The maximum of the Si content is 3.5%. The roll steels examined here contain a suitable amount of cobalt and are advantageous nor means to improve their properties, especially silicon.

In the examples that follow, the roll steels claimed are the same as those in use Roll steels compared.

Examples

The following table shows the composition of the steels examined. From these steels were produced in a known way by casting, forging, machining and hardening cold rolling.

Curve 7oC 7th Cr 7oCo 1 0.75 1.80 2.5 2 0.75 1.80 1.5 3 0.75 1.80 1.0 4th 0.75 1.85 0.5

There is a tendency that the higher the Co content the hardness of the steel decreases.

60 example 1 Example 2 Counter
Example 3 c,%;
Si, * /.
Mn,%
«5 Ct ₅ ⁰ Z ₀ ..
Mo, · /, ......
Co, ° / o 0.80
* 0.28
0.26
2.51 \.
0.32
0.09
2.70 0.80
0.75
0.26
2.38
0.32
0.15
2.70 0.81
0.28
0.35
2.50
0.29
0.13
0

The hardening treatment is carried out by heating the roller to temperatures above Ac 3 and then subsequently Quenching with water.

The rollers according to Examples 1 and 2 are kept at temperatures of 940 ^° C. for more than 5 minutes and then quenched with water.

These rolls are suitable for use in four-roll stands known per se. They have a diameter of 100 mm and a length of 330 mm in the final state.

The surface hardness of the rollers after cooling is 865 to 925 HV. The thickness of the hardened In example 2, the layer is approximately 14 to 16 mm.

In the case of example 1, the cooling temperature was about 30 ^° C. higher than in example 3 in order to increase the thickness of the hardened layer.

Metal plates were cold rolled using the three properly hardened rolls described. This showed the following:

Numerous cracks were found on the conventionally assembled rolls, mainly on those parts that were tempered at 674 HV due to the development of heat. For example 1 and 2 According to the present invention, cracks were found only in those parts of the rollers that were set to values of less than 354 HV had dropped. As a result, it was confirmed that the composite according to the present invention Rollers have excellent crack resistance.

Claims (3)

Claims: 1. Use of a steel with 0.60 to 1.30% carbon 0.25 to 3.50% silicon 0.15 to 1.60% manganese 1.00 to 3.50% chromium
0.30 to 8.00% cobalt
as well as, if applicable up to 2.0% up to 2.0% up to 2.0% up to 2.0% nickel
Molybdenum vanadium tungsten remainder iron with impurities caused by melting as a material for the production of surface-hardened Cold rolling. 2. Use of a steel according to claim 1 with the proviso that the Si content is 0.25 to 0.50% for the purpose of claim 1. 3. Use of a steel according to claim 1 with the proviso that the Si content is 0.50 to 3.50% is used as a material for the production of surface-hardened materials that are particularly resistant to stress cracking Cold rolling. 1 sheet of drawings