EP0352597A1 - Process for producing hot-rolled strip or heavy plates - Google Patents

Abstract

The invention relates to a process for the production of hot rolled strip or heavy plates from stainless and refractory steels or from forgeable alloys on a nickel basis with a final thickness in the range of 5 to 60 mm by the production of a slab from monobloc casting or by continuous casting and heating the slab at a temperature above 1100 DEG C. followed by the hot rolling of the slab and accelerated cooling of the product rolled to the end thickness. The characterizing feature of the invention is that the heated slab is rolled without interruptions first to a maximum of 1/6 of its initial thickness, mainly by deformation passes in which the degree of deformation pass in the thickness direction is greater than the degrees of deformation shown by curve A in FIG. 1, in dependence on the surface temperature of the product. Then finish rolling is performed to the end thickness, mainly by deformation passes in which the degree of deformation per pass in the thickness direction is greater than the degrees of deformation shown by curve B1 or curve B2 in FIG. 1, in dependence on the surface temperature of the product and the pause between two adjacent passes as parameters. The surface temperature of the finish rolled product must be not less than 1030 DEG C., if the product contains up to 1.0% molybdenum and not less than 1050 DEG C., if the product contains more than 1.0% molybdenum. At the latest 100 seconds following finish rolling, the product is cooled at an accelerated rate with a speed in the core of more than 3 K/sec, more particularly more than 5 K/sec, to a temperature which is equal to or lower than 650 DEG C.

Description

The invention relates to a method for producing hot strip or heavy plates from rustproof and heat-resistant steels or from wrought alloys based on nickel with a final thickness in the range from 5 to 60 mm by producing a slab from ingot casting or by continuous casting, heating the slab at a temperature above of 1,100 ° C, subsequent hot rolling of the slab and accelerated cooling of the product rolled to its final thickness.

A method according to the preamble of claim 1 for the production of austenitic stainless steel plates with high corrosion resistance and high mechanical strength both at ambient temperature and at high temperatures is known from DE-OS 36 17 907. It can be seen from this prior art document that the steel plates, i.e. Heavy plates made of rust-proof austenitic steels of the composition specified in the publication after the roughing and finishing rolling and the subsequent cooling in air to room temperature usually have to be subjected to a subsequent heat treatment or solution annealing. This is carried out so that the hardening caused by the deformation is broken down and precipitations of intermetallic or carbidic phases are dissolved, which negatively affect the corrosion resistance of the product. In order to achieve this goal, the subsequent solution annealing must generally take place at temperatures of more than 1,000 ° C. and correspondingly long holding times, which are sufficient to bring the precipitates back into solution. At the same time, the deformation-related solidification is reduced as a result of recovery and recrystallization. Accordingly, the stainless steel plates or heavy plates produced by this conventional method have in the solution-annealed state with regard to their mechanical properties, e.g. Strength and toughness, as well as corrosion resistance, a property profile that is characterized by low mechanical strength.

The solution annealing that follows the roughing and finishing rolling and the subsequent cooling in air to room temperature however, points to more than 1,000 ° C due to the reheating of the already rolled product. and the required holding times high production costs and longer production times. Furthermore, this subsequent annealing process usually involves additional scaling of the product, which can cause its surface quality to deteriorate. As a rule, this means an additional effort for the required final scaling of the finished rolled product.

Among other things Proceeding from these disadvantages, the object of the patent application described and claimed in DE-OS 36 17 907 is to create a process for producing austenitic stainless steel plates which have better corrosion resistance and tensile strength both at ambient temperatures and at higher temperatures, without the need to use a downstream heating furnace as is required in the conventional process for subsequent solution annealing.

As a solution to this problem, it is proposed to first heat the slab from an austenitic stainless steel grade, which usually requires subsequent solution annealing and from which the steel plate is to be produced, to a temperature of more than 1,000 ° C. The heated slab is then hot-rolled in the recrystallization area of the austenite and preferably also in the non-recrystallization area with a finish-rolling temperature of more than 800 ° C. Finishing rolling in the non-recrystallization area is essential in order to achieve a higher mechanical strength. Immediately after the finish rolling to the final thickness, there is an accelerated cooling with an average cooling rate of more than 2 K / s to a temperature of at least 550 ° C. Provided that these rolling and cooling conditions are met, the subsequent subsequent solution treatment is usually no longer necessary.

As the exemplary embodiments show, in particular in comparison with finished rolled steel plates made from the same austenitic stainless steel grades, with the same final thickness, but in solution-annealed condition, the product produced by this process has a much better mechanical and comparable corrosion resistance. A higher strength is achieved in particular if hot rolling is also carried out in the non-recrystallization area. In particular, it can be seen from the exemplary embodiments that in this known method, with a final thickness of the product of 20 mm, the heating and heating temperature for the slab is preferably in the range from 1,100 to 1,200 ° C., and the finish-rolling temperature is in the range from 900 to 970 ° C, that is in any case less than 1,000 ° C and immediately after finish rolling with a temperature loss of only about 10 ° C the accelerated cooling begins, to a value of 500 ° C, preferably 300 ° C, in particular down to room temperature. Only when the final thickness of the product or heavy plate is 40 mm, in particular 100 mm, does a finish rolling temperature of more than 1,000 ° C result.

If hot strip or heavy plates are now to be produced from rustproof and heat-resistant steels or from wrought alloys based on nickel with the composition given in Table 1, but with a property profile that corresponds to the property profile of the same product in the solution-annealed state, this is a previously known method for the production of Heavy plates, especially hot strip, are not suitable for the following reasons:

If heavy plates with a final thickness of less than 60 mm are pre-rolled and finish-rolled warm using this process, the finish-rolling temperature drops so much that a property profile comparable to that of heavy plates in solution-annealed condition, for example in terms of strength, toughness and corrosion resistance, cannot be set. Rather, the method known from DE-OS 36 17 907 basically gives a higher mechanical strength. However, if this is not desired with regard to the processing and use properties of the heavy plates, the finished rolled plates must then be subjected to a subsequent solution treatment, provided that they have a final thickness of less than 60 mm, in particular less than 40 mm.

The same also applies to the production of hot strip, which has to be subjected to solution annealing due to the high temperature losses after the final rolling due to the small strip thickness, particularly during the finish rolling phase. In addition, this heat treatment, which is usually carried out in a continuous furnace with a subsequent pickling line, restricts the production of hot strip to a maximum final thickness of approximately 10 mm, although it is in principle possible to also produce hot strip with a final thickness of the order of magnitude Finished roughly 20 mm warm.

Therefore, if the hot strip and the heavy plates should have a property profile as in the solution-annealed state, then heat treatment or solution annealing is still essential to break down the deformation-related hardening and to dissolve excretions. For the reasons mentioned, hot strip and heavy plate with a final thickness of less than 60 mm are primarily affected, in particular those with a thickness in the range between 8 and 40 mm. Accordingly, if an increase in the strength properties is not desired, then with the method known from DE-OS 36 17 907 only heavy plates can be safely produced without subsequent solution treatment, which have a final thickness of more than 60 mm, but are rarely used in practice . On the other hand, so far only the production of hot strip with a final thickness of less than about 8 or 10 mm has been possible without problems, which, however, has to be solution annealed in any case after the finish rolling.

However, in the production of hot-rolled strip and heavy plates from rustproof and heat-resistant steels or from wrought alloys based on nickel according to Table 1, it is increasingly necessary to use these products over the largest possible range, i.e. also with a thickness in the range of 5 to 60 mm, preferably 8 to 40 mm, to produce by a uniform process.

In this regard, EP-OS 0 144 694 discloses a modified process for the production of flat, band-shaped or plate-shaped semifinished products, for example with a final cross section of 15 mm × 40 mm, from a stainless austenitic or martensitic steel, which, however, provides for solution annealing. With this The workpiece is first heated from the stainless steel with the composition specified in the publication to a high temperature of the order of 1200 ° C. and heated through at this temperature. It is then pre-rolled and finish-rolled warm at a temperature in the range of 1,000 to 1,100 ° C in such a way that complete recrystallization of the rolling stock is ensured by sufficient deformation during the rolling process. After finish rolling to final thickness, solution annealing and subsequent quenching of the semi-finished product in water take place from this temperature range to almost room temperature. An essential feature of this process is that the solution annealing immediately following the rolling process is carried out in a heat after the last or the last rolling passes and the workpiece is then quenched directly from the solution annealing temperature in water without any additional treatment.

Since, as a rule, the finish rolling temperature is too low for immediate quenching, the workpiece produced according to this method must first be heated again by means of a heater after the finish rolling. As an alternative, this method provides for a roller heating system, which is intended to largely prevent premature and excessive cooling of the workpiece during rolling in order to prevent the finished workpiece from being reheated to the required solution solution and quenching temperature of more than 1,000 ° C. However, this additional heating for the reheating of the finished rolled product and in particular the proposed roller heating would mean a considerable additional outlay in the production of hot strip or heavy plates, which was previously customary.

The invention has for its object to provide a method of the type mentioned, according to which products in the form of hot strip or heavy plates with the composition given in Table 1 are hot-rolled and have a property profile after accelerated cooling, for example with regard to strength, toughness and corrosion resistance , which corresponds to that of solution annealed hot strip or heavy plate.

According to the invention, this object is achieved in accordance with the measures specified in the characterizing part of claim 1 as follows:

Initially, slabs are produced from ingot casting or by continuous casting from rustproof and heat-resistant steels or from wrought alloys based on nickel with the composition given in Table 1 and heated through before the hot rolling at a temperature of more than 1,100 ° C. Immediately afterwards, the hot-rolling of the heated slabs begins without interruption to a maximum of 1/6 of their initial thickness, ie they are reduced to a maximum of 1/6 of their initial thickness with the shortest possible break times between the individual deformation stitches in extreme cases. Hot rolling is predominantly carried out with deformation stitches in which the degree of deformation per stitch in the direction of thickness is greater than the degrees of deformation indicated by curve A in FIG. The degree of deformation phi is defined as
phi = 1n h _n-1 / h _n with
h _n = rolling stock thickness after the nth pass and
h _n-1 = rolling stock thickness after the (n-1) th pass.

Since more than 50% of the selected deformation stitches have a degree of deformation which is greater than the degrees of deformation indicated by curve A in FIG. 1, this means that the hot rolling takes place predominantly in the recrystallization region, as in the method known from EP-OS 0 144 694 , which makes the very coarse-grained starting structure largely homogeneous in this first rolling phase, free of microscopic tears and fine-grained due to the high temperature.

The initial thickness of the slab or slabs is usually in the order of about 150 to 250 mm. If, however, the slabs produced by continuous casting only have a thickness of the order of about 50 mm or less, the reduction in the product in them can also be used according to the invention the first rolling phase. Usually, however, a pre-rolling phase is followed by finish rolling to the final thickness, which according to measure ac) in claim 1 takes place above a minimum temperature which is dependent on the molybdenum content of the product and which must not be undercut.

In contrast to the usual practice described in the two aforementioned documents, it is essential to the invention for the finish rolling according to the invention to the final thickness that not only in the recrystallization area, i.e. with deformation stitches with degrees of deformation according to curve A in Figure 1 and larger, but that the degrees of deformation of the majority of the selected deformation stitches must be greater than that depending on the surface temperature of the product and the pause time between two adjacent deformation stitches as a parameter by the Curve B1 or B2 in Figure 1 given degrees of deformation. Curve B1 applies to a pause time between two adjacent stitches of less than 10 s (preferably hot strip) and curve B2 applies to a pause time between two adjacent stitches of more than 10 s (preferably heavy plate).

By using these degrees of deformation specified according to the invention, it is primarily achieved that the structure is recrystallized homogeneously and finely grained during finish rolling and the deformation-related solidification is broken down without the need for subsequent heat treatment for recrystallization before the accelerated cooling of the product, as is the case with that from the EP -OS 0 144 694 previously known method is provided. In addition, this measure largely compensates for heat losses due to conduction and radiation.

If the hot strip or heavy plate is rolled to the final thickness above the minimum temperature specified in claim 1 according to the invention in ac. 1, the accelerated cooling takes place no later than 100 s thereafter at a core speed of more than 3 K / s, preferably more than 5 K / s, except for a temperature equal to or less than 650 ° C.

With the method according to the invention, hot strip and heavy plates made of the steels specified in Table 1 can have one end thickness in the range of 5 to 60 mm and with a property profile that corresponds to the mechanical properties and the corrosion resistance of solution-annealed hot strips and heavy plates. In contrast to this, the strips and sheets produced according to the invention, however, have a more uniform, in particular very fine-grained and largely excretion-free structure, as a result of which their processing and use properties are improved. In particular, thin strips and sheets with a preferred final thickness in the range from 8 to 40 mm can now be hot-rolled to the final thickness without additional heat input during the rolling out in such a way that subsequent solution annealing is no longer required .

The properties of the strips and sheets produced by the process according to the invention can be further improved and optimized by hot-rolling and the subsequent accelerated cooling in accordance with the measures specified in subclaims 2 to 7. The method according to claim 3 relates to the production of hot strip and the method according to claim 4 to the production of heavy plates. If at the same time all the deformation stitches of the roughing phase have a degree of deformation which is greater than the degrees of deformation indicated by curve A in FIG. 1, hot strip and heavy plates can be e.g. Manufacture with optimal values in terms of strength, toughness and corrosion resistance.

The method according to the invention can preferably be applied to the production of hot strip and heavy plates from rustproof and heat-resistant steels with an analysis according to claims 8 to 11 and 14 to 17 and from a wrought nickel base alloy with the composition specified in claims 12 and 13. If the method is preferably applied to rustproof and heat-resistant austenitic steels with the composition according to claims 16 and 17, hot strip and / or heavy plates with high toughness and increased corrosion resistance are obtained, which afterwards as a finished product are easy to process with regard to hot forming, cold forming and welding have.

When the measures according to the invention are applied to stainless austenitic steels with the composition specified in claim 17, which form delta ferrite during solidification, it is advantageous if the requirements for corrosion resistance are correspondingly high if these steels are alloyed to a content of delta ferrite below 10 %, preferably less than 5%. This can be done according to the invention by lowering the contents of ferrite-forming elements, but preferably by - with the exception of carbon - increasing the contents of austenite-forming alloy elements individually or in groups. The following applies according to Table 3:
DF [%] = (2.9004 * Cr _{ä q} - 2.084 * Ni _{ä q} ) - 25.62, with
Cr _{ä q} = Cr + Mo + 1.5 * Si + 0.5 * Nb + 4 * Ti + 3 * Al and
Ni _{ä q} = Ni + 0.5 * Mn + 30 * (C + N) + 0.5 * Cu.

The invention is explained in more detail below on the basis of individual exemplary embodiments:

Table 1 shows the composition of those stainless and heat-resistant steels and wrought alloys based on nickel, from which hot strip and heavy plates can be produced by the process according to the invention. Of these alloys, the five different alloys specified in Table 3 were selected, from which hot strip with a final thickness of 10 and 15 mm and heavy plates with a final thickness in the range from 10 to 40 mm were produced by the process according to the invention. These are two stainless austenitic steels with a molybdenum content of less than 1.0%, two further stainless austenitic steels with a molybdenum content of more than 1.0% and a nickel-based alloy with the composition given in Table 3.

From these five different alloys, preliminary slabs with a thickness in the range of 170 to 265 mm were first produced and then heated to a temperature of more than 1,100 ° C. and heated through at this temperature. The hot strip and the heavy plates were then heated from them According to the method according to the invention, the slabs were first rolled out to a final thickness in a roughing phase and in a subsequent finishing rolling phase, before the finished rolled product was accelerated to a temperature of less than 650 ° C. at a rate of more than 3 K / s. The degrees of deformation per pass were selected both in the roughing phase and in the finish-rolling phase according to the dependence of the degree of deformation, according to the invention, shown in Table 2 and shown in FIG. Specifically, the hot rolling and cooling conditions, according to which the five different alloys given in Table 3 to form hot strip (W) and heavy plates were rolled out to final thickness, are given in Table 4. The corresponding conditions of hot strip and heavy plate not produced according to the invention are also given. Table 5 compares the results obtained with hot rolled strip and heavy plate produced according to the invention, with solution annealed and not annealed and with solution annealing.

If hot strip and heavy plates with the composition given in Table 3 are hot-rolled and finish-rolled by the process according to the invention in accordance with claim 1 and then accelerated at the latest 100 s after finish-rolling, these strips and plates have a yield strength and tensile strength according to Table 5, which are comparable with the corresponding sizes of solution-annealed strips and sheets. As the corresponding column in Table 5 shows, the strips and sheets produced according to the invention have an improved, more uniform, fine-grained and largely excretion-free structure, which has a positive effect on the processing and use properties of these strips and sheets. The elongation and notched impact strength are also comparable with the corresponding values of the products in the solution-annealed state and are in all cases within a narrow range.

As the comparative examples according to the invention, which are likewise given in Table 5, show in particular, the process leads to products with higher strength values, in particular higher yield strength, lower elongation with surface cracks and with a coarser-grain mixed structure if the measures aa) (roughing phase), ab) (finish rolling phase), ac) (final rolling temperature) and b) (accelerated cooling) are not observed individually or in combination. In this regard, the following results in detail:

As shown in Comparative Examples 1.7 and 3.6 in particular, hot rolling in the roughing phase with degrees of deformation of the deformation passages that are predominantly or in the majority smaller than the degrees of deformation indicated by curve A in FIG. 1 can lead to harmful surface cracks on the product. For this reason alone, the strips and sheets obtained cannot be used. The desired values for the yield strength, tensile strength and elongation cannot be set in these cases either. In this regard, the product has mechanical properties that differ from the property profile of the product in the solution-annealed state.

Hot rolling in the recrystallization area and at high temperatures, as is already known from EP-OS 0 144 694, on the other hand, is not sufficient to set the properties desired for the hot strip and the heavy plates. As the comparative examples 1.8, 3.8 and 4.8 in Table 4 and the associated values for the yield strength, tensile strength, elongation and notched impact strength in Table 5 show - in these cases measure aa) according to the invention is fulfilled - in particular a much higher yield strength and a lower one Elongation is set if the hot rolling condition according to the feature ab) in claim 1 is not met. It is therefore not only important that the products in the recrystallization area, i.e. are hot-rolled with degrees of deformation which are greater than the degrees of deformation indicated by curve A in FIG. 1, but the measures according to the invention from) and ac) of claim 1 must also be met, in particular in the finish rolling phase.

As can also be seen from Tables 4 and 5, a homogeneous and fine-grained structure which is improved compared to the solution-annealed condition can be set provided the hot rolling conditions in the finish rolling phase for hot strip according to subclaims 2 and 3 and for heavy plates according to subclaims 2 and 4 can be set. Fulfill on the other hand, the hot rolling conditions in the finish rolling phase, in addition to measure ac), only the feature ab) according to claim 1, a generally fine-grained structure is also generally achieved, but to a small extent also has coarse grain. In these cases too, the hot strips and heavy plates produced according to the invention have comparable mechanical properties and corrosion resistance to the products in the solution-annealed state.

Overall, the exemplary embodiments according to the invention and the comparative examples in Tables 4 and 5 show that hot strip and heavy plates made of rustproof and heat-resistant steels or of wrought alloys based on nickel with the composition given in Table 1 with a final thickness in the range from 5 to 60 mm, preferably in the range from 8 to 40 mm, can be produced by the process according to the invention with a property profile which corresponds to the property profile of the corresponding strips and sheets in the solution-annealed state. The strips and sheets produced according to the invention advantageously have a homogeneous and fine-grained structure that is largely free of excretions, which further improves their processing and use properties. Furthermore, the method according to the invention now makes it possible, in particular, to produce hot strip with a final thickness greater than approximately 5 mm in a simple and inexpensive manner by controlled hot rolling with subsequent accelerated cooling without the need for subsequent solution annealing. Table 1 Stainless and heat-resistant steels Wrought alloys based on Ni ferritic and martensitic austenitic / ferritic austenitic Alloy element Alloy content in mass% carbon ≦ 0.35 ≦ 0.05 ≦ 0.15 ≦ 0.1 manganese ≦ 2.5 ≦ 10.0 ≦ 20.0 ≦ 4.0 silicon ≦ 1.5 ≦ 1.5 ≦ 4.0 ≦ 4.0 nickel ≦ 3.0 4 - 7 ≦ 35 (Rest Ni) chrome 6 - 30.0 10 - 30.0 10 - 30.0 10 - 30 molybdenum ≦ 3.0 ≦ 5.0 ≦ 7.0 ≦ 10 titanium ≦ 1.5 ≦ 1.5 ≦ 1.5 ≦ 1.5 Tantalum and / or niobium ≦ 1.5 ≦ 1.5 ≦ 1.5 ≦ 1.5 copper ≦ 5.0 ≦ 5.0 ≦ 5.0 aluminum ≦ 1.5 ≦ 0.5 ≦ 1.0 ≦ 0.5 nitrogen ≦ 0.5 ≦ 0.5 ≦ 0.5 ≦ 0.5 Other V ≦ 0.5 V ≦ 1.0 Fe ≦ 45 S ≦ 0.5 S ≦ 0.3 (Rest of Fe) (Rest of Fe) (Rest of Fe) Forming temperature T _U (rolling stock surface) ° C Critical degree of deformation φ * Roughing phase Finishing rolling phase Curve A Curve B 1 ** Curve B₂ *** 1200 0.046 (0.061) (0.083) 1150 0.066 0.085 0.127 1100 0.094 0.116 0.178 1050 0.137 0.163 0.238 1030 0.163 0.191 0.269 1000 0.196 0.227 0.305 980 0.223 0.254 0.332 * = The individual values have been rounded to 0.001. ** = for break times less than 10 sec. *** = for break times longer than 10 sec. Serial no. Material according to DIN Chemical composition in mass% Delta ferrite DF (%) according to * C. Si Mn P S Cr Mon Ni N Al Ti 1 1.4301 0.035 0.34 1.45 0.023 0.003 18.0 0.20 8.7 0.057 3.3 2nd 1.4541 0.048 0.51 1.50 0.026 0.003 17.2 0.50 9.1 0.46 9.7 3rd 1.4404 0.027 0.29 1.58 0.026 0.008 16.7 2.16 11.1 0.044 1.1 4th 1.4571 0.045 0.33 1.33 0.022 0.003 16.9 2.12 10.5 0.39 4.1 5 2.4858 0.013 0.32 0.79 0.015 0.003 20.7 2.85 39.25 0.10 0.80 - * DF (%) = (Cräg 2.9004 - Niäg 2.084) - 25.62 with Cräg = Cr + Mo + 1.5 Si + 0.5 Nb + 4 Ti + 3 Al Niäg = Ni + 30 (C + N) + 0.5 Mo + 0.5 Cu Steel (DIN no.) Product No. Pre-slab thickness mm Final thickness mm Roughing phase Finishing rolling phase Final rolling temp. (T _E) ° C Transfer time t _t s Cooling rate ° C / s Total stitches of which with φ> A _(TU) Total stitches of which with φ> B _(TU) 1.4301 E 1.1 170 10th 4th 4th 8th 7 1065 25th 30th 1.2 W " 15 5 4th 7 6 1035 <5 15 1.3 " " 4th 4th 6 6 1070 35 > 5 1.4 " 40 4th 4th 4th 3rd 1090 20th 6 nE 1.5 " 10th 4th 3rd 8th 5 1020 > 5 1.6 " 10th 4th 3rd 12 6 1040 <5 > 5 1.7 " 15 8th 3rd 8th 5 1035 > 5 1.8 " 20th 4th 3rd 10th 5 1035 8th 1.4541 E 2.1 W 170 10th 5 4th 7 6 1065 <5 > 5 2.2 215 " 4th 3rd 8th 8th 1110 <10 > 5 2.3 170 15 4th 4th 6 6 1075 <10 20th 2.4 " " 4th 3rd 8th 6 1065 25th > 6 2.5 " 20th 4th 3rd 6 6 1080 80 7 nE 2.6 170 10th 5 3rd 7 4th 1000 > 5 2.7 215 10th 6 4th 12 6 1040 1.0 2.8 170 15 6 3rd 8th 5 1035 > 5 2.9 " 20th 4th 3rd 10th 5 1020 25th 1.4404 E 3.1 W 170 10th 5 3rd 7 6 1075 <5 > 5 3.2 " 15 4th 4th 6 6 1105 <10 > 5 3.3 " 15 4th 3rd 8th 7 1090 <10 > 5 3.4 " 20th 4th 3rd 8th 6 1080 > 5 nE 3.5 " 10th 4th 4th 8th 5 1020 <10 > 5 3.6 " 10th 6 2nd 10th 6 1050 > 5 3.7 " 15 6 3rd 8th 5 1030 > 5 3.8 " 15 4th 3rd 10th 5 1060 > 5 3.9 " 15 4th 3rd 10th 6 1060 0.6 1.4571 E 4.1 170 10th 4th 3rd 8th 8th 1100 20th > 5 4.2 215 15 4th 4th 8th 8th 1125 30th > 5 4.3 " " 4th 3rd 10th 8th 1090 <10 > 5 4.4 265 20th 4th 4th 10th 8th 1085 50 > 5 4.5 " 40 4th 4th 6 5 1050 20th > 5 nE 4.6 170 10th 4th 3rd 12 6 1000 > 5 4.7 " " 4th 2nd 8th 6 1050 > 5 4.8 215 15 4th 3rd 12 6 1060 <10 > 5 4.9 170 15 4th 3rd 8th 7 1060 0.6 2.4858 E 5.1 W 180 15 5 3rd 7 6 1075 <5 > 5 nE 5.2 W " " 7 6 7 3rd 975 E - according to the invention nE - not according to the invention W - hot strip Steel (DIN no.) Product No. *) R _p0.2 *) R _m *) A₅ *) A _v (ISO-V) Grain size G according to DIN 50601 Delta ferrite content ***) Corrosion tests N / mm² % PT -196 ° C % (J) (J) 1.4301 E 1.1 300 625 50 179 8 - 9 3 - 6 Requirements met according to: 1; 2; 3rd 1.2 W 310 629 50 175 1.3 295 616 55 211 8th 1.4 281 596 62 201 7 nE 1.5 408 672 36 111 1.6 390 650 38 130 8 + 4 **) 1.7 350 656 40 145 Surface cracks 1.8 405 665 41 134 1.L 265- 605- 45- 170- 4 - 5 1 - 3 345 635 60 190 1.4541 E 2.1 W 298 595 50 170 2 - 4.5 Requirements met according to: 1; 2; 3rd 2.2 280 590 55 185 2.3 255 587 55 184 8 - 9 2.4 272 594 53 186 2.5 259 575 58 164 7-8 nE 2.6 450 679 35 98 2.7 440 655 40 105 not required n. 2; 3rd 2.8 385 627 43 128 9 + 5 **) 2.9 395 641 41 129 2.L 245- 580- 40 150- 7-8 1.5 - 2 345 640 53 195 1.4404 E 3.1 W 320 618 49 175 9 1.5 - 4 Requirements met according to: 1; 2; 3; 4th 3.2 281 590 54 189 125 8th 3.3 344 601 52 185 154 8 - 9 3.4 280 575 54 180 121 7-8 nE 3.5 479 692 33 102 3.6 324 611 44 163 9 + 5 **) Surface cracks 3.7 435 670 38 125 3.8 405 615 41 135 3.9 340 610 42 145 3.L 250- 570- 46- 175- 50- 4 + 5 0.5 - 2 310 605 55 230 65 1.4571 E 4.1 270 585 53 195 3 - 7 Requirements met according to: 1; 2; 3rd 4.2 267 578 57 190 4.3 275 587 54 198 4.4 270 605 54 191 4.5 300 625 50 178 nE 4.6 542 715 36 105 4.7 430 625 38 115 4.8 405 624 39 120 4.9 425 674 32 96 not required n. 3; 4th 4.L 275- 560- 43- 145- 2 - 5 315 605 55 195 2.4858 E 5.1 W 290 605 50 205 Beginning req .: 1; 2; 3rd nE 5.2 W 545 716 28 96 5.L 265- 600- 45 190- 295 625 50 215 E - according to the invention nE - not according to the invention L - solution annealed W - hot strip * - across the rolling direction ** - Mixed grain structure *** - measured with the Förster probe Corrosion tests: 1 - Strauss test according to DIN 50914 2 - mod. String test according to SEP 1877 3 - ASTM 262 Pract. B Ruey test according to DIN 50921

Claims (19)

1. A method for producing hot strip or heavy plates from rustproof and heat-resistant steels or from wrought alloys based on nickel with a final thickness in the range from 5 to 60 mm by producing a slab from ingot casting or by continuous casting, heating the slab at a temperature above 1,100 ° C , subsequent hot rolling of the slab and accelerated cooling of the product rolled to final thickness, characterized in that a) the heated slab without interruptions
aa) initially rolled up to a maximum of 1/6 of its initial thickness predominantly with deformation stitches in which the degree of deformation per stitch in the thickness direction is greater than the degree of deformation indicated by curve A in FIG. 1 as a function of the surface temperature of the product,
ab) subsequently, to the final thickness, predominantly finish-rolling with forming passes, in which the degree of deformation per pass in the thickness direction is greater than that depending on the surface temperature of the product and the pause time between two adjacent passes as parameters by curve B1 or B2 in Fig. 1 specified degrees of deformation,
ac) where the surface temperature of the finished rolled product
- not below 1.030 ° C, provided that the product contains up to 1.0% molybdenum and
- does not fall below 1,050 ° C if the product contains more than 1,0% molybdenum and b) the product is cooled at the latest 100 s after the finish rolling at a core speed of more than 3 K / s, in particular more than 5 K / s, accelerated to a temperature which is equal to or less than 650 ° C. 2. The method according to claim 1, characterized in that all the deformation stitches with which the heated slab is first rolled up to a maximum of 1/6 of its initial thickness are carried out with a degree of deformation which is greater than that depending on the surface temperature of the product degrees of deformation indicated by curve A in FIG. 1. 3. The method according to any one of claims 1 or 2, characterized in that at least 2/3 of the deformation stitches with which the product is rolled to its final thickness are carried out with a degree of deformation which is greater than that depending on the surface temperature of the product and the pause time between two adjacent stitches as parameters given by curve B1 in FIG. 1. 4. The method according to any one of claims 1 or 2, characterized in that at least 3/4 of the deformation stitches with which the product is rolled to its final thickness are carried out with a degree of deformation which is greater than that depending on the surface temperature of the product and the pause time between two adjacent stitches as parameters given by curve B2 in FIG. 1. 5. The method according to any one of claims 1 to 4, characterized in that the finished rolled product is slowly cooled in air to room temperature following the accelerated cooling. 6. The method according to any one of claims 1 to 5, characterized in that the finished rolled product, if it consists of a stainless and heat-resistant, ferritic, martensitic or austenitic-ferritic steel, is accelerated to a temperature which is equal to or less than Is 400 ° C. 7. The method according to any one of claims 1 to 6, characterized in that the surface temperature of the finished rolled product, if it consists of a stainless and heat-resistant, ferritic or martensitic steel, before the accelerated cooling
- not below 980 ° C, provided that the product contains up to 1.0% molybdenum and
- not lower than 1,000 ° C if the product contains more than 1.0% molybdenum. 8. The method according to any one of claims 1 to 7, characterized in that the slab is made of a stainless and heat-resistant, ferritic or martensitic steel, consisting of max. 0.35% C, max. 2.5% Mn, max. 1.5% Si, max. 3.0% Ni, 6.0 to 30.0% Cr, max. 3.0% Mo rest iron and the inevitable impurities. 9. The method according to claim 8, characterized in that the stainless and heat-resistant, ferritic or martensitic steel additionally max. 1.5% Ti, max. 1.5% Ta and / or Nb, max. 1.5% Al, max. 0.5% N, max. 0.5% V, max. 0.5% S can be added individually or in groups. 10. The method according to any one of claims 1 to 6, characterized in that the slab is made of a stainless and heat-resistant, austenitic-ferritic steel, consisting of max. 0.05% C, max. 10.0% Mn, max. 1.5% Si, 4.0 to 7.0% Ni, 10.0 to 30.0% Cr, max. 5.0% Mo, balance iron and the inevitable impurities. 11. The method according to claim 10, characterized in that the stainless and heat-resistant, austenitic-ferritic steel additionally max. 1.5% Ti, max. 1.5% Ta and / or Nb, max. 5.0% Cu, max. 0.5% Al, max. 0.5% N can be added individually or in groups. 12. The method according to any one of claims 1 to 5, characterized in that the slab is made of a wrought alloy based on nickel, consisting of max. 0.1% C, max. 4.0% Mn, max. 4.0% Si, 10.0 to 30.0% Cr, max. 10.0% Mo rest nickel and the inevitable impurities. 13. The method according to claim 12, characterized in that the wrought nickel-based alloy additionally max. 1.5% Ti, max. 1.5% Ta and / or Nb, max. 5.0% Cu, max. 0.5% Al, max. 0.5% N, max. 45.0% Fe can be added individually or in groups. 14. The method according to any one of claims 1 to 5, characterized in that the slab is made of a stainless and heat-resistant, austenitic steel, consisting of max. 0.15% C, max. 20.0% Mn, max. 4.0% Si, max. 35.0% Ni, 10.0 to 30.0% Cr, max. 7.0% Mo rest iron and the inevitable impurities. 15. The method according to claim 14, characterized in that the stainless and heat-resistant austenitic steel additionally max. 1.5% Ti, max. 1.5% Ta and / or Nb, max. 5.0% Cu, max. 1.0% Al, max. 0.5% N, max. 1.0% V, max. 0.3% S can be added individually or in groups. 16. The method according to any one of claims 14 or 15, characterized in that the slab from a stainless and heat-resistant, austenitic steel with max. 3.0% Si, 7.0 to 35.0% Ni, max. 0.5% Al, max. 0.035% S. 17. The method according to claim 16, characterized in that the stainless and heat-resistant austenitic steel with 7.0 to 20.0% Ni, 15.0 to 25.0% Cr, max. 5.0% Mo is alloyed. 18. The method according to claim 17, characterized in that the delta ferrite content in the stainless and heat-resistant austenitic steel used is set to a value less than 10%, preferably by controlling the amounts of the alloying elements Ni, N, Mn added to the steel and / or Cu. 19. Application of the method according to one of claims 1 to 18 to the production of hot strip or heavy plates with a final thickness in the range of 8 to 40 mm.

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