WO2024001078A1 - 80 mm thick 690 mpa-grade ultra-high strength and toughness marine steel plate and preparation method therefor - Google Patents

Abstract

The present invention relates to an 80 mm thick 690 MPa-grade ultra-high strength and toughness marine steel plate and a preparation method thereof. The composition thereof by mass percentage are: C: 0.08%-0.10%, Si: 0.20%-0.30%, Mn: 1.10%-1.25%, P≤0.007%, S≤0.002%, Nb: 0.020%-0.030%, Ti: 0.010%-0.020%, V: 0.030%-0.045%, Cr: 0.40%-0.60%, Ni: 1.40%-1.50%, Cu: 0.15%-0.25%, Mo: 0.25%-0.35%, and Als: 0.015%-0.045%, controlling Pcm≤0.33%, Ceq≤0.64%, and the remainder being Fe and inevitable impurity elements. For the 80 mm 690 MPa-grade ultra-high strength marine steel plate of the present invention, all performance indicators meet the certification requirements of China Classification Society EH690 steel, having a -300mV (relative to an Ag/AgCl reference electrode) saturated corrosion current density ≤ 1.90mA/cm2, and a density of corrosion-active inclusions ≤ 9/mm2. The product has high strength, low-temperature resistance, corrosion resistance and other characteristics.

Description

An 80mm thick 690MPa grade ultra-high strength and toughness marine steel plate and its preparation method

Related applications:

This application claims priority to Chinese patent application 2022107478038, titled "An 80mm thick 690MPa ultra-high-strength marine steel plate and its preparation method" and submitted on June 29, 2022. This application is included by reference here.

Technical field

The invention belongs to the technical field of ultra-high strength marine steel production, and specifically relates to an 80mm extra-thick 690MPa grade ultra-high strength and toughness marine steel plate and a preparation method thereof.

Background technique

As people's exploration of the marine field continues to deepen, the matching of extra-thick steel for ships and marine engineering and its research, development and production have become a top priority. The complex and ever-changing marine service environment requires the extra-thick steel. Industrial steel needs to have excellent comprehensive properties such as high strength, high toughness, easy welding, and resistance to seawater corrosion.

There are many deficiencies in the current preparation technology of extra-thick 690MPa grade steel plates. In terms of composition design, some add a large amount of alloying elements, which increases production costs, and others cause difficulties in the production process or subsequent processing and use of steel plates; in terms of production processes, most of them have the problem of long heat treatment processes.

Chinese patent CN 111304551B proposes an ultra-high-strength EH690 extra-thick steel plate and its manufacturing method. In the patent, C: 0.10% ~ 0.17%, Si: 0.25% ~ 0.45%, Mn: 0.90% ~ 1.30%, S ≤0.003%, P≤0.010%, V: 0.041%～0.076%; Als: 0.03%～0.05%, N: 0.004%～0.013%, Ni: 1.40%～1.80%, Cr: 0.60%～1.00%, Mo : 0.30% ~ 0.50%, Nb: 0.021% ~ 0.04%, Cu: 0.43% ~ 0.50%, Ti ≤ 0.02%, in which more V, Cr, Mo, Cu and other elements are added. In this patent, a heat treatment process of quenching + sub-temperature quenching + tempering is required after rolling.

The patent application with publication number CN110846577A proposes a 690MPa grade medium manganese steel with a low yield ratio and its manufacturing method. The composition contains 4.1% to 4.7% Mn element, and the large addition of Mn element will cause problems in steelmaking. And the continuous casting process brings huge difficulties. Continuous casting production is easy to cause accidents. Although medium manganese steel has high low-temperature toughness, the rolled steel plates are prone to problems such as unqualified flaw detection and corner cracks.

The application with the publication number CN 112251670A and the patent CN 102965592B both proposed a method for preparing extra-thick 690MPa grade marine steel. 0.001% ~ 0.0015% and 0.001% ~ 0.003% B were added to the chemical composition respectively to improve the strength of the steel plate. , the addition of B element will significantly increase the tendency of welding cracks in the steel plate, which is not conducive to subsequent processing. In these preparation technologies, in order to obtain the required properties, a normalizing heat treatment of 890 to 920°C is required before quenching + high-temperature heat treatment or a low-temperature heat treatment below 300°C is required after quenching + high-temperature tempering heat treatment. It is not conducive to the industry needs to improve production efficiency and reduce costs.

Contents of the invention

In view of the shortcomings and defects of the existing technology, the present invention aims to provide an 80mm 690MPa grade ultra-high-strength marine steel plate and a preparation method thereof. The performance index of the 80mm 690MPa ultra-high-strength marine steel plate of the present invention meets the certification requirements of China Classification Society EH690 steel; at the same time, the -300mV (relative to Ag/AgCl reference electrode) saturated corrosion current density is ≤1.90mA/cm ² , The density of corrosion-active inclusions is ≤9/mm ² . The product has excellent comprehensive properties such as high strength and toughness, low temperature resistance, and corrosion resistance.

In order to achieve the above objectives, the first aspect of the present invention provides a composition design of an 80mm690MPa grade ultra-high-strength marine steel plate, adopting the following technical solution:

An 80mm690MPa grade ultra-high-strength marine steel plate. The chemical composition mass percentages in the steel plate are: C: 0.08% ~ 0.10%, Si: 0.20% ~ 0.30%, Mn: 1.10% ~ 1.25%, P ≤ 0.007%, S≤0.002%, Nb: 0.020%～0.030%, Ti: 0.010%～0.020%, V: 0.030%～0.045%, Cr: 0.40%～0.60%, Ni: 1.40%～1.50%, Cu: 0.15%～ 0.25%, Mo: 0.25% ~ 0.35%, Als: 0.015% ~ 0.045%, the rest are Fe and inevitable impurity elements, control Pcm ≤ 0.33%, Ceq ≤ 0.64%.

Among them: Ceq=C+Mn/6+(Cr+Mo+V)/5+(Ni+Cu)/15;

Pcm=C+Si/30+Mn/20+Cu/20+Ni/60+Cr/20+Mo/15+V/10+5B.

In the above-mentioned 80mm690MPa grade ultra-high-strength marine steel plate, as a preferred embodiment, the unavoidable impurity elements in terms of mass percentage are H≤0.0002%, O≤0.003%, N≤0.004%, and B≤0.0005 %, As≤0.006%, Sb≤0.010%, Sn≤0.020%, Pb≤0.010%, Bi≤0.010%.

The functions of the main alloys in the 80mm690MPa ultra-high-strength marine steel plate are as follows:

For extra-thick steel plates, Cr can effectively improve the hardenability to compensate for the strength loss caused by thickness, and can also improve the corrosion resistance of the steel plates. However, once the content is too high, it will lead to the formation of Cr-Mn complex oxides with low melting points, which will easily cause surface cracks in the steel plate during hot processing and will also deteriorate the welding performance. Therefore, the Cr content in the present invention is controlled at 0.40% to 0.60%.

Ni is the element that most obviously improves the low-temperature toughness of extra-thick steel plates. Adding appropriate Ni can reduce the stacking fault energy of the crystal, facilitate the slip movement of dislocations, and improve the impact toughness; at the same time, Ni can promote the formation of dense protection on the surface of the steel plate. The rust layer is removed and the corrosion resistance of the steel plate is improved. However, too high Ni content is not conducive to ensuring welding performance. Therefore, the Ni content in the present invention is controlled at 1.40% to 1.50%.

Cu can improve the corrosion resistance and strength of steel, improve weldability and machinability, etc. However, too high Cu content will increase the hot brittleness tendency of the steel plate. Therefore, the Cu content in the present invention is controlled at 0.15% to 0.25%.

Mo is an element that improves hardenability. It can expand the γ phase area, delay the formation of precipitated ferrite, effectively improve the strength, and can also significantly improve the stability of the strength and toughness properties in the thickness direction of extra-thick steel plates. However, too high Mo content will deteriorate the weldability of the steel plate, so the present invention controls the Mo content to 0.25% to 0.35%.

Nb can effectively refine grains and can also play a role in precipitation strengthening; however, due to the limitation of C and the influence of heating temperature, Nb with too high content cannot be fully dissolved. Therefore, the Nb content in the present invention is controlled between 0.020% and 0.030%.

Ti can also have the effect of refining grains and precipitation strengthening, and significantly improves the low-temperature impact toughness of steel plates. However, when the content is too high, it is easy to form large particles of TiN and lose the fine grain effect. Therefore, the present invention controls the Ti content between 0.010% and 0.020%.

V is a grain-refining element in steel and also has the effect of precipitation strengthening. When the addition amount is less than 0.02%, the effect is not obvious; when it is greater than 0.05%, the toughness and weldability of the steel are reduced. Therefore, the V content in the present invention is controlled between 0.030% and 0.045%.

Al can fix the free N in the steel and improve the low-temperature toughness of the steel plate and welded HAZ. Moreover, the dispersion and precipitation of AlN will inhibit the growth of austenite grains during the heating process, uniformly refine the austenite grain size, and improve the impact toughness. However, excessive Al content will increase the number of inclusions in the steel, increase the size of the inclusions, and reduce the internal quality of the steel plate, affecting the hot processing performance, welding performance and cutting performance of the steel. Therefore, the present invention controls the Al content within 0.020%～0.050%.

Ceq: Controlling the carbon equivalent index is beneficial to ensuring the strength and weldability of the steel plate. The present invention controls Ceq ≤ 0.64%.

Pcm: Controlling the cold crack sensitivity coefficient is beneficial to ensuring the welding performance of the product. The present invention controls Pcm ≤ 0.33%.

Impurity elements in steel, such as S, P, etc., will increase the degree of segregation of continuous casting billets and worsen the uniformity of structural properties in the thickness direction of the steel plate. Therefore, the S and P contents are controlled below 0.005% and 0.010% respectively; B is easily enriched at grain boundaries, which reduces the low-temperature impact performance and fatigue performance of the steel plate, and also significantly increases the tendency of welding cracks. Therefore, B is controlled to be ≤ 0.0005%; At the same time, other unavoidable impurity elements As ≤ 0.006%, Sb ≤ 0.010%, Sn ≤ 0.020%, Pb ≤ 0.010%, Bi ≤ 0.010%, H ≤ 0.0002%, O ≤ 0.003%, N ≤ 0.004%.

The second aspect of the present invention provides a method for preparing the above-mentioned 80mm690MPa grade ultra-high-strength marine steel plate, including converter smelting, LF+RH double refining, continuous casting, billet heating, rolling, and heat treatment, specifically:

(1) Converter smelting

Use KR-treated molten iron, molten iron S ≤ 0.008%; nickel plate, copper plate, and ferromolybdenum are added along with scrap steel; smelted using a double-slag deep dephosphorization process, and the final slag alkalinity is controlled at R = 3.0 to 4.0 to achieve initial early stage The slag is well slag-formed during the process, and the final slag is thoroughly formed; metal manganese, ferro-niobium, ferro-vanadium, low-carbon ferro-chromium, and ferro-silicon are used for alloying. The alloy is added when 1/4 of the steel is placed, and the molten steel is added to 3/4 of the time. When the addition is complete; add ferromanganese according to 3-3.5kg/t steel for deoxidation.

(2)LF+RH refining

Bottom-blown argon stirring is used throughout the process, aluminum particles, calcium carbide, and silicon carbide are used to adjust the slag, titanium wire is used to adjust the Ti component, and aluminum wire is used to adjust the Al component. The alkalinity of the final slag is controlled to be above 2.5 as much as possible, and the LF refining time is ≥50 minutes, among which the soft Blow time ≥10min.

RH refining adopts this processing mode. Ensure that the vacuum degree is within 30Pa and the pure degassing time is ≥5 minutes. After RH treatment, feed calcium aluminum wire 1-1.5m/t, soft blowing time ≥14min, RH smelting time ≥50min.

(3)Continuous casting

Full protection casting is adopted, using peritectic steel mold slag, the liquidus temperature is 1510~1520℃, the superheat is controlled within 20℃, the pulling speed of the 300mm thick continuous casting billet used is 0.70-0.90m/min, and it is cast in the sector section The solidification end of the billet adopts light reduction technology, and the billet is placed in the pit and stacked for slow cooling for ≥72 hours.

(4) Cast billet heating

The billet is cold loaded into the furnace; a multi-stage heating and warming method is adopted, the soaking section temperature is 1190-1240℃, the soaking time is ≥60min, the tapping temperature is 1200-1230℃, and the total heating and warming time is 290-310min. On the one hand, it ensures The cast slab is burned evenly and thoroughly while preventing excessive growth of austenite grains; before the hot cast slab is rolled, a high-pressure water dephosphorization treatment is performed.

(5)Rolling

The rolling process is a two-stage rolling process of rough rolling and finish rolling. Rough rolling is recrystallization rolling, and the number of rough rolling passes is ≤ 5, and the reduction rate of at least 2 passes (thickness reduction in a single pass/entry thickness, the same below) is ≥ 19% to pass the large reduction. The rate can fully refine the austenite grains, providing structural guarantee for improving the strength and toughness of thick steel plates. The thickness of the intermediate billet after rough rolling is 120-130mm. Finish rolling is non-recrystallized rolling, the finishing rolling opening temperature is 835-865°C, and the number of finishing rolling passes is ≤ 7. Preferably, the number of finishing rolling passes is 5 to make full use of the number of passes. The cumulative effect of deformation and the forced phase transformation mechanism induced by defects within the deformed austenite grains promote the emergence of a large number of deformation bands, twins and dislocations inside the austenite grains, creating conditions for ferrite phase deformation nuclei and making the steel plate Improved strength and toughness. Control the thickness of the intermediate billet obtained after rough rolling to reasonably distribute the reduction of rough rolling and finishing rolling, and improve the properties of the steel plate, especially the impact toughness of the core and the uniformity of properties in the thickness direction.

After rolling, the cooling process is controlled to increase the ferrite nucleation rate and form fine and dispersed precipitates, further improving the strength and toughness of the steel plate. The opening cooling temperature is 800~820℃, the final cooling temperature is 550~590℃, and the cooling speed is controlled at 6~10℃/s. After that, the steel plate is moved into a slow cooling pit or stacked for slow cooling to ensure the full progress of the phase change process and improve the structural uniformity of the thick steel plate. The slow cooling time is ≥ 48 hours.

(6)Heat treatment

The heat treatment method of quenching + high temperature tempering is adopted.

According to the composition design, the Ac3 temperature of the steel plate of the present invention is about 850°C. In order to ensure the acquisition of fine and uniform austenite grains, in order to obtain a fine martensite structure after quenching, and to reduce the low hardness ferrite in the quenching structure Phase content, quenching heating temperature should be 30~50℃ above Ac3. Considering that the composition contains strong carbide-forming elements such as Nb, V, and Ti, which can increase the austenite grain coarsening temperature, the quenching temperature is set to 920±5°C to accelerate the dissolution of alloy carbides. Increase the stability of supercooled austenite and improve the hardenability of steel. The heating time is 1.3~1.6min/mm×plate thickness, and the holding time is 30±3min. After the steel plate is heated and kept warm, it enters the quenching machine for quenching treatment. This invention uses an ultra-wide overall slit type quenching machine designed by Northeastern University. The high-pressure water spray system of its cooling water system includes 2 sets of slit nozzles and 4 sets of high-density Type I nozzles with a length of 3640mm. The low-pressure water spray system includes 18 Set of high-density type II nozzles, length 12600mm. The water pressure in the high-pressure section is 0.7~0.9bar, and the water pressure in the low-pressure section is 0.3~0.4bar. According to the principle of "low roller speed + large water volume quenching", the roller speed of the quenching machine is 1.6-1.8m/min, the water volume in the high-pressure section is 5376-6067m ³ /h, and the water volume in the low-pressure section is 3499-3888m ³ /h; the preferred process plan is, The roller speed of the quenching machine is 1.6m/min, the water volume in the high-pressure section is 5376m ³ /h, and the water volume in the low-pressure section is 3888m ³ /h; the roller speed of the quenching machine is 1.8m/min, the water volume in the high-pressure section is 6067m ³ /h, and the water volume in the low-pressure section is 3499m ³ / h. The ratio of the water volume of the upper nozzle to the water volume of the lower nozzle is approximately 1:1.4 to ensure the symmetry and uniformity of the steel plate during the quenching process. In this way, through the cooling of the high-pressure section, the steel plate is fully quenched to complete all phase transformations, and the low-pressure section further takes away the heat conducted from the inside of the steel plate to the surface to prevent residual heat tempering, so that the temperature of the steel plate finally drops to room temperature.

High temperature tempering can eliminate the complex internal stress of the steel plate after rapid cooling quenching and make the steel plate have excellent comprehensive mechanical properties. In the present invention, the tempering heating temperature is 600±5℃, the heating time is 2~2.5min/mm*plate thickness, and the heat preservation time is 30±3min. After the steel plates are released from the furnace, they are cooled to room temperature by blowing cold air on the cooling bed. It is necessary to avoid stacking and storing the steel plates within a short time after being released from the furnace to prevent the steel plates from becoming brittle due to high temperature tempering.

In this way, an 80mm 690MPa grade ultra-high-strength marine steel plate is obtained. The main performance indicators are: yield strength ≥690MPa, tensile strength 770~940MPa, elongation after break ≥16%, -40°C core transverse impact energy ≥100J, - 40℃ CTOD≥0.15mm, -300mV (relative to Ag/AgCl reference electrode) saturated corrosion current density ≤1.90mA/cm ² , corrosion active inclusion density ≤9/mm ² .

Compared with the existing technology, the advantages of the present invention are:

(1) Good performance uniformity. The present invention provides high-quality cast slab raw materials by controlling the composition, purity and gas content in the steelmaking process; scientifically designs the heating, rolling, and post-rolling controlled cooling processes, and adopts two stages of large reduction and reasonable operation in the rough rolling stage. Measures such as reduction distribution are used to make the deformation penetrate into the core of the steel plate; the heat treatment process is optimized to obtain a high-strength and toughness structure throughout the thickness section, with excellent mechanical properties, transverse and longitudinal impact, aging impact and cold bending, and uniform performance in the thickness direction. Fully meets the certification requirements of EH690 steel of the classification society.

(2) Low cost and high production efficiency. Optimize the composition design, use a reasonable controlled rolling and cooling process, combine plastic deformation and post-rolling cooling with solid-state phase change, give full play to the effects of solid solution strengthening, precipitation strengthening and fine grain strengthening, and ensure that the effects of alloy elements are fully exerted; By optimizing the roller speed of the quenching machine, the water volume in the high-pressure and low-pressure sections, and the design of the upper and lower water ratios, the heat treatment effect of thick steel plates is improved. After quenching and high-temperature tempering, steel plates with excellent performance can be obtained without going through other heat treatment processes. , shortening the production process and reducing production costs.

(3) Excellent corrosion resistance. This invention utilizes high-clean molten steel smelting technology, high-penetration rolling technology and optimized heat treatment processes to obtain a low-inclusion, highly homogeneous structure with good corrosion resistance, greatly improving the corrosion potential of the steel plate matrix itself; at the same time, Cr+Cu+ The addition of Ni alloy element can effectively promote the formation of a dense, protective rust layer with good adhesion on the surface of the steel plate, preventing corrosive media such as H ₂ O, O ₂ and Cl ^- from penetrating into the steel matrix, ensuring that the product can survive in strong marine corrosive environments. service safety.

Description of drawings

Figure 1 is a 500x metallographic structure near the surface of the steel plate prepared in Example 1 of the present invention;

Figure 2 is a 500x metallographic structure at 1/4 of the thickness of the steel plate prepared in Example 1 of the present invention;

Figure 3 is a 500x metallographic structure at 1/2 thickness of the steel plate prepared in Example 1 of the present invention;

Figure 4 is a -300mV (vs.Ag/AgCl) potentiostatic polarization curve of the steel plate prepared in Example 1 of the present invention;

Figure 5 shows the corrosion active inclusions in the steel plate produced in Example 1 of the present invention under a 50x field of view.

Detailed ways

The present invention will be described in further detail below with reference to the drawings and specific embodiments.

Example 1:

According to the chemical composition shown in Table 1, according to the above smelting process, highly clean molten steel is obtained through converter smelting and LF+RH double refining, and a 300mm thick continuous casting billet is obtained by casting. The cast slab is heated, the tapping temperature is 1210°C, the furnace time is 300 minutes, rough rolling is performed for 5 passes (pass 5 is passed), the reduction rates of the 3rd and 4th passes are 19.3% and 23.7% respectively, and the rough rolling is completed. The thickness of the final intermediate billet is 130mm; after the temperature reaches 845°C, the finishing rolling stage begins, with 7 passes of finishing rolling (pass 7 is empty); controlled cooling is performed at a speed of about 8°C/s, with an opening cooling temperature of 815°C and a final cooling temperature of 815°C. 590℃. After rolling, it is slowly cooled in the slow cooling pit for more than 48 hours. The quenching temperature is heated to 920°C and kept for 30 minutes. The roller speed of the quenching machine is 1.8m/min. The water volume in the high-pressure section is 6067m ³ /h. The water volume in the low-pressure section is 3499m ³ /h. The ratio of the water volume in the upper nozzle to the water volume in the lower nozzle is 1:1.4. The tempering heating temperature is 600°C and the temperature is kept for 30 minutes. It can be seen from Figures 1 to 3 that the near-surface structure is dominated by tempered sorbite. As it develops toward the center, the content of dispersed granular bainite, ferrite, and pearlite gradually increases. The inspection was carried out in accordance with the test methods and requirements in the China Classification Society's "Materials and Welding Rules" (2021). The main tensile properties and impact performance indicators are shown in Table 2, and the corrosion resistance performance indicators are shown in Table 3.

Example 2:

According to the chemical composition shown in Table 1, according to the above smelting process, highly clean molten steel is obtained through converter smelting and LF+RH double refining, and a 300mm thick continuous casting billet is obtained by casting. The casting billet is heated. The heating and tapping temperature of the continuous casting billet is 1230°C. The furnace time is 290 minutes. There are 5 rough rolling passes. The reduction rates of the 4th and 5th passes are 19.1% and 22.3% respectively. After the rough rolling is completed, the intermediate billet The thickness is 120mm; after the temperature reaches 860°C, the finishing rolling stage begins, with 5 passes of finishing rolling; controlled cooling is carried out at a speed of about 10°C/s, with an opening cooling temperature of 803°C and a final cooling temperature of 559°C. After rolling, it is slowly cooled in the slow cooling pit for more than 48 hours. The quenching temperature is heated to 920°C and kept for 30 minutes. The roller speed of the quenching machine is 1.6m/min. The water volume in the high-pressure section is 5376m ³ /h. The water volume in the low-pressure section is 3888m ³ /h. The ratio of the water volume in the upper nozzle to the water volume in the lower nozzle is 1:1.4. The tempering heating temperature is 600°C and the temperature is kept for 30 minutes.

Comparative ratio:

In order to illustrate the influence of the quenching machine parameters on the performance of the steel plate, the present invention uses an embodiment of the quenching machine adjustment process as a comparative example to illustrate. Comparative Example The smelting and casting implementation methods are the same as those in Example 2. The casting billet is heated. The heating and tapping temperature of the continuous casting billet is 1230°C. The furnace time is 290 minutes. There are 5 rough rolling passes. The reduction rates of the 4th and 5th passes are 20.0% and 21.6% respectively. After the rough rolling is completed, the intermediate billet The thickness is 120mm; after the temperature reaches 850℃, the finishing rolling stage begins, with 5 passes of finishing rolling; controlled cooling is carried out at a speed of about 10℃/s, the opening cooling temperature is 805℃, and the final cooling temperature is 562℃. After rolling, it is slowly cooled in the slow cooling pit for more than 48 hours. The quenching temperature is heated to 920°C and kept for 30 minutes. The roller speed of the quenching machine is 2.0m/min. The water volume in the high-pressure section is 6255m ³ /h. The water volume in the low-pressure section is 3287m ³ /h. The ratio of the water volume in the upper nozzle to the water volume in the lower nozzle is 1:1.4. The tempering heating temperature is 600°C and the temperature is kept for 30 minutes.

Table 2 shows the tensile properties and impact properties of the steel plates obtained in Examples and Comparative Examples. The steel plate prepared according to the method of the present invention has a yield strength of ≥690MPa, a tensile strength of 770-940MPa, an elongation after break of ≥16%, a -40°C transverse impact energy of ≥100J, and good performance uniformity in the thickness direction. The strength and toughness of the comparative example are obviously lower than those of the examples, especially the 1/4 thickness and core impact properties cannot meet the performance requirements of E690 steel.

Table 3 shows the corrosion resistance performance indicators of the steel plates obtained in Examples and Comparative Examples. The saturated corrosion current density was measured using an Autolab electrochemical workstation. A three-electrode system was used. The Ag/AgCl electrode was the reference electrode and the Pt electrode was the auxiliary electrode. The steel plate was sampled and a sample with an exposed area of ¹ cm was used as the working electrode. In the artificial seawater solution (Composition shown in Table 4) The sample was subjected to anodic polarization at a constant potential of -300mV, and the changes in polarization current and the corrosion current density after stabilization were recorded. Figure 4 shows the -300mV (vs.Ag) of the steel plate prepared in Example 1. /AgCl) potentiostatic polarization curve. When measuring the density of corrosion-active inclusions, sample the steel plate to make a 10mm*10mm*5mm sample, polish it and soak it in artificial seawater for 20 minutes. After taking it out, rinse it with alcohol, dry it with cold air, take several photos continuously under a 50x light microscope and calculate the density of corrosion-active inclusions. Figure 5 shows the corrosion-active inclusions in the steel plate prepared in Example 1 under a 50x field of view.

Table 1 Chemical composition (wt%) of steel plates in the examples and comparative examples of the present invention

Table 2 Properties of steel plates according to the embodiments of the present invention and comparative examples

Table 3 Corrosion resistance performance indicators of steel plates according to the embodiments of the present invention

Table 4 Composition of artificial seawater

This method can be realized by the upper and lower limits of the interval values of the process parameters (such as temperature, time, etc.) and the interval values of the present invention, and the embodiments will not be listed one by one here.

Contents not described in detail in the present invention may adopt conventional technical knowledge in the field.

Finally, it should be noted that the above embodiments are only used to illustrate the technical solutions of the present invention and are not limiting. Although the present invention has been described in detail with reference to the embodiments, those of ordinary skill in the art should understand that modifications or equivalent substitutions may be made to the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, and they shall all be covered by the scope of the present invention. within the scope of the claims.

Claims (10)

1. An 80mm thick 690MPa grade ultra-high-strength marine steel plate, characterized in that the chemical composition of the steel plate in mass percentage is: C: 0.08% ~ 0.10%, Si: 0.20% ~ 0.30%, Mn: 1.10% ~ 1.25 %, P≤0.007%, S≤0.002%, Nb: 0.020%～0.030%, Ti: 0.010%～0.020%, V: 0.030%～0.045%, Cr: 0.40%～0.60%, Ni: 1.40%～1.50 %, Cu: 0.15% ~ 0.25%, Mo: 0.25% ~ 0.35%, Als: 0.015% ~ 0.045%, and control Pcm ≤ 0.33%, Ceq ≤ 0.64%, and the rest are Fe and inevitable impurity elements.
2. The 80mm thick 690MPa grade ultra-high-strength marine steel plate according to claim 1, characterized in that the mass percentage content of each component in the inevitable impurity elements is: H≤0.0002%, O≤0.003%, N ≤0.004%, B≤0.0005%, As≤0.006%, Sb≤0.010%, Sn≤0.020%, Pb≤0.010%, Bi≤0.010%.
3. The 80mm thick 690MPa grade ultra-high strength and toughness marine steel plate according to claim 1 or 2, characterized in that the main performance indicators of the ultra-high strength and toughness marine steel plate are: yield strength ≥ 690MPa, tensile strength 770-940MPa, after fracture Elongation ≥16%, -40℃ central transverse impact energy ≥100J, -40℃ CTOD≥0.15mm, relative to Ag/AgCl reference electrode -300mV saturated corrosion current density ≤1.90mA/cm ² , corrosion active inclusions Density ≤9 pieces/mm ² .
4. A method for preparing an 80mm thick 690MPa grade ultra-high-strength marine steel plate according to any one of claims 1-3, the preparation method including the following steps: converter smelting, LF+RH double refining, continuous casting, and casting billet Heating, rolling, heat treatment.
5. The preparation method according to claim 4, characterized in that, in the converter smelting, KR-treated molten iron is used, the molten iron S≤0.008%, nickel plate, copper plate, and ferromolybdenum are added along with scrap steel, and double slag deep dephosphorization is used Process smelting, using metal manganese, ferroniobium, ferrovanadium, low carbon ferrochromium, ferrosilicon for alloying, and adding ferromanganese for deoxidation according to 3-3.5kg/t steel.
6. The preparation method according to claim 4, characterized in that in the LF+RH double refining, argon is bottom-blown throughout the LF refining process, the refining time is ≥50 min, and the soft blowing time is 10-15 min; RH refining ensures that the vacuum degree is at 30 Pa Within the range, the pure degassing time is ≥5min. After the RH treatment, feed the calcium aluminum wire 1-1.5m/t, the soft blowing time is 15-20min, and the RH smelting time is ≥50min.
7. The preparation method according to claim 4, characterized in that, in the continuous casting, full-process protective casting is used, the superheat is controlled within 20°C, and the pulling speed of the 300mm thick continuous casting billet is 0.70-0.90m/min, and the obtained The slab is slowly cooled for more than 72 hours.
8. The preparation method according to claim 4, characterized in that during the heating of the cast slab, a multi-stage heating and temperature rising method is adopted, the soaking section temperature is 1190-1240°C, the soaking time is ≥ 60 min, and the tapping temperature is 1200-1230°C. , the total heating time is 290-310min.
9. The preparation method according to claim 4, characterized in that the rolling includes two stages of rough rolling and finish rolling; the rough rolling is recrystallization rolling, the number of rough rolling passes is ≤5, and it is guaranteed that at least The reduction rate of 2 passes is ≥19%, the thickness of the intermediate billet after rough rolling is 120-130mm; the finish rolling is unrecrystallized rolling, the finishing rolling opening temperature is 835-865°C, and the number of finishing rolling passes is ≤7 , the opening cooling temperature of the rapid cooling process after rolling is 800~820℃, the final cooling temperature is 550~590℃, and the cooling speed is 6~10℃/s.
10. The preparation method according to claim 4, characterized in that, in the heat treatment, a quenching + high temperature tempering process is adopted; the quenching temperature is 920±5°C, the heating time is 1.3~1.6min/mm×plate thickness, and the heat preservation time is 30± 3min; the water pressure in the high-pressure section of the quenching machine is 0.7~0.9bar, the water pressure in the low-pressure section is 0.3~0.4bar, the roller speed is 1.6-1.8m/min, the water volume in the high-pressure section is 5376-6067m ³ /h, and the water volume in the low-pressure section is 3499-3888m ³ / h; The ratio of the water volume of the upper nozzle to the water volume of the lower nozzle is about 1:1.4, the tempering heating temperature is 600±5℃, the heating time is 2~2.5min/mm*plate thickness, the holding time is 30±3min, and it is air-cooled after being released.

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