CN112522640B - High-strength fire-resistant weather-resistant steel plate/belt and production method thereof - Google Patents
High-strength fire-resistant weather-resistant steel plate/belt and production method thereof Download PDFInfo
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- C22C38/00—Ferrous alloys, e.g. steel alloys
- C22C38/18—Ferrous alloys, e.g. steel alloys containing chromium
- C22C38/40—Ferrous alloys, e.g. steel alloys containing chromium with nickel
- C22C38/58—Ferrous alloys, e.g. steel alloys containing chromium with nickel with more than 1.5% by weight of manganese
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- B22D—CASTING OF METALS; CASTING OF OTHER SUBSTANCES BY THE SAME PROCESSES OR DEVICES
- B22D11/00—Continuous casting of metals, i.e. casting in indefinite lengths
- B22D11/06—Continuous casting of metals, i.e. casting in indefinite lengths into moulds with travelling walls, e.g. with rolls, plates, belts, caterpillars
- B22D11/0622—Continuous casting of metals, i.e. casting in indefinite lengths into moulds with travelling walls, e.g. with rolls, plates, belts, caterpillars formed by two casting wheels
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- B22D11/00—Continuous casting of metals, i.e. casting in indefinite lengths
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- B22D11/0637—Accessories therefor
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- C21D8/00—Modifying the physical properties by deformation combined with, or followed by, heat treatment
- C21D8/02—Modifying the physical properties by deformation combined with, or followed by, heat treatment during manufacturing of plates or strips
- C21D8/0205—Modifying the physical properties by deformation combined with, or followed by, heat treatment during manufacturing of plates or strips of ferrous alloys
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- C21D8/00—Modifying the physical properties by deformation combined with, or followed by, heat treatment
- C21D8/02—Modifying the physical properties by deformation combined with, or followed by, heat treatment during manufacturing of plates or strips
- C21D8/0221—Modifying the physical properties by deformation combined with, or followed by, heat treatment during manufacturing of plates or strips characterised by the working steps
- C21D8/0226—Hot rolling
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Abstract
A high-strength fire-resistant weather-resistant steel plate/belt and a production method thereof are disclosed, which comprises the following components by weight percent: 0.02-0.06% of C, 0.1-0.55% of Si, 0.4-1.7% of Mn, less than or equal to 0.03% of P, less than or equal to 0.007% of S, 0.30-0.80% of Cr, 0.10-0.60% of Cu, 0.20-0.60% of Mo, 0.01-0.08% of Nb, 0.004-0.010% of N, als<0.001%, B0.001-0.006%, total oxygen [ O ]] T :0.007‑0.020%,Mn/S>250 (c); pcm is less than or equal to 0.27 percent; the balance being Fe and unavoidable impurities. The invention selectively adds Mo/Nb/Cr micro-alloy elements and B elements in steel; controlling the alkalinity of slag, the type and melting point of inclusions in steel, the free oxygen content in molten steel and the content of acid-soluble aluminum Als; casting a cast strip by adopting twin-roll thin strip continuous casting, carrying out on-line hot rolling, and cooling the rolled strip steel in an air atomization cooling mode. The material has low yield ratio, excellent earthquake resistance and excellent fire resistance, and is an ideal material in the field of steel for earthquake resistance and fire prevention.
Description
Technical Field
The invention belongs to a twin-roll thin strip continuous casting process, and particularly relates to a high-strength fire-resistant weather-resistant steel plate/strip and a production method thereof.
Background
The traditional thin strip steel is produced by casting blanks with the thickness of 70-200mm through multi-pass continuous rolling, and the traditional hot rolling process flow is as follows: continuous casting, casting blank reheating and heat preservation, rough rolling, finish rolling, cooling and coiling, namely firstly, a casting blank with the thickness of about 200mm is obtained through continuous casting, the casting blank is reheated and heat preserved, then rough rolling and finish rolling are carried out to obtain a steel strip with the thickness generally larger than 2mm, and finally laminar cooling and coiling are carried out to the steel strip to complete the whole hot rolling production process. The difficulty is relatively great if steel strip with a thickness of less than 1.5mm inclusive is to be produced, which is usually done by subsequent cold rolling and annealing of the hot rolled strip. And the process flow is long, the energy consumption is high, the number of unit equipment is large, the capital construction cost is high, and the production cost is high.
The thin slab continuous casting and rolling process flow is as follows: continuous casting, heat preservation and soaking of a casting blank, hot continuous rolling, cooling and coiling. The main differences between the process and the traditional process are as follows: the thickness of a casting blank in the thin slab process is greatly reduced to 50-90mm, and because the casting blank is thin, the casting blank can be reduced to the required specification before finish rolling only by carrying out 1-2 times of rough rolling (when the thickness of the casting blank is 70-90 mm) or not carrying out the rough rolling (when the thickness of the casting blank is 50 mm) on the casting blank, while the casting blank in the traditional process can be repeatedly rolled for multiple times; and the casting blank of the thin slab process directly enters a soaking pit furnace for soaking and heat preservation without cooling or supplementing a small amount of heat, so that the thin slab process greatly shortens the process flow, reduces the energy consumption and the investment, thereby reducing the production cost. However, the strength of steel is improved and the yield ratio is improved due to the faster cooling speed of the thin slab continuous casting and rolling, so that the rolling load is increased, and the thickness specification of a hot rolled product which can be economically produced is unlikely to be too thin, generally more than or equal to 1.5mm, as shown in Chinese patents CN200610123458.1, CN200610035800.2 and CN200710031548.2.
The ESP realizes the continuous casting of the slab continuously, cancels the slab flame cutting and the heating furnace with the functions of heat preservation, soaking and slab transition, and greatly shortens the length of the whole production line to about 190 meters. The thickness of a plate blank continuously cast by the continuous casting machine is 90-110mm, the width of the plate blank is 1100-1600mm, the plate blank continuously cast by the continuous casting machine plays a role in heat preservation and soaking through a section of induction heating roller way, and then the plate blank sequentially enters the working procedures of rough rolling, finish rolling, layer cooling and coiling to obtain a hot rolled plate. The process realizes endless rolling, can obtain the hot rolled plate with the thinnest thickness of 0.8mm, expands the specification range of the hot rolled plate, and has the output of a single production line reaching 220 kiloton per year. At present, the process is rapidly developed and popularized, and a plurality of ESP production lines are operated and produced in the world at present.
The process flow shorter than the thin slab continuous casting and rolling is a thin strip continuous casting and rolling process, the thin strip continuous casting technology is a leading-edge technology in the fields of metallurgy and material research, the emergence of the technology brings a revolution to the steel industry, the production process of steel strips in the traditional metallurgy industry is changed, continuous casting, rolling, even heat treatment and the like are integrated into a whole, the produced thin slab is subjected to online hot rolling once to form a thin steel strip, the production process is greatly simplified, the production period is shortened, and the length of the process line is only about 50 m; the equipment investment is correspondingly reduced, the product cost is obviously reduced, and the method is a low-carbon and environment-friendly hot-rolled thin strip production process. The twin-roll thin strip continuous casting process is a main form of the thin strip continuous casting process and is the only thin strip continuous casting process for realizing industrialization in the world.
The typical process flow of twin roll strip casting is shown in fig. 1, molten steel in a ladle 1 is directly poured into a molten pool 7 surrounded by two oppositely rotating and rapidly cooled crystallizing rolls 8a and 8b and side sealing devices 6a and 6b through a ladle long nozzle 2, a tundish 3, a submerged nozzle 4 and a distributor 5, the molten steel is solidified to form a solidified shell on the circumferential surfaces of the rotating crystallizing rolls 8a and 8b and gradually grows, a cast strip 11 with the thickness of 1-5mm is formed at the minimum gap (nip point) between the rolls 8a and 8b, the cast strip 11 is fed into a rolling mill 13 through a guide plate 9 to be rolled into thin strip with the thickness of 0.7-2.5mm, then is cooled through a cooling device 14, is cut by a flying shear device 16, and is finally fed into a coiler 19 to be coiled.
In recent years, with the continuous emergence of large buildings and high-rise buildings at home and abroad, in order to avoid the collapse of the buildings caused by the sudden decrease of the strength of the building steel due to the heating when the buildings are in fire, and great loss of lives and properties of residents, the fire protection process design of the building steel is widely regarded by people internationally, and the fire protection process design of the building steel becomes one of necessary measures for ensuring the building safety. The strength and the bearing capacity of the steel for the common building are rapidly reduced when the steel is heated, and the requirement of fire safety cannot be met. In order to improve the fire resistance of buildings constructed by using common construction steel, the conventional method is to adopt measures such as spraying a fire-resistant coating or covering a fire-proof plate, and the like, but now a great amount of fire-resistant steel is used, so that the fire-resistant coating or the fire-proof plate can be thinned or omitted, the steel can be ensured to keep higher strength level at high temperature, the construction period can be shortened, the quality of the buildings can be reduced, the safety of the buildings can be improved, the construction cost can be reduced, and the economic benefit and the social benefit are obvious. Meanwhile, most of the constructional steel is exposed in the air, and the service life is long, so that the steel has weather resistance on the basis of fire resistance, and a brand-new fire-resistant weather-resistant steel product is derived. Under the large application background, the existing fire-resistant weather-resistant steel plate/belt is increasingly applied to industries and fields of building steel with fire protection requirements, tower and mast columns, engineering machinery, industrial structures and the like, and is particularly widely applied to places with high fire safety requirements, such as high-rise buildings, large public buildings, high-grade houses and the like.
The fire-resistant weathering steel is required to have good high-temperature performance, but is different from the heat-resistant steel which is used at high temperature for a long time, and the heat-resistant steel is required to have good high-temperature strength and high-temperature stability, and generally adopts high alloy steel. The fire-resistant weathering steel is loaded at normal temperature, but is required to maintain higher yield strength under the short-time (usually 1-3 h) high-temperature condition of fire, and can gain precious time for the safe evacuation of personnel, so that the fire-resistant weathering steel belongs to the category of low-alloy structural steel, and excessive expensive alloy elements are not suitable to be added in the component design.
The safety design specifications for the steel structure in Japan stipulate: 2/3 of the yield strength of steel at normal temperature corresponds to the long-term allowable stress value of the material, and when a fire breaks out, if the yield point of the fire-resistant weathering steel can still keep the value, the building can not collapse. Therefore, the yield strength of the fire-resistant weathering steel at a certain high temperature is required to be not less than 2/3 of the yield strength at room temperature. In order to improve the seismic resistance of steel structures, it is always desirable to improve the seismic energy absorbing capacity of steel as much as possible. If the yield ratio (σ) of the steel s /σ b ) Higher, local stress concentration and local large deformation can be generated when an earthquake occurs, and at the moment, the steel knotThe structure can only absorb less energy, so the low yield ratio is beneficial to improving the energy absorbed by the building structure when earthquake occurs, and the yield ratio of the anti-seismic fire-resistant weathering steel is generally required to be less than or equal to 0.8.
One of the keys to the development of fire resistant weathering steels is to set the fire temperature at which it is desired to achieve high temperature strength. Mo-containing steel which can resist the high temperature of 900-1000 ℃ has been researched in European Creusot-Loire steel works, but the Mo-containing steel is not popularized and applied due to high cost. In order to determine the fire-resistant temperature which is best matched with the reduction of the production cost and the consumption of the fire-resistant materials, the new-day iron is subjected to high-temperature tensile tests on several typical steels with the tensile strength of 400-780MPa, and the tests show that: yield strength (. Sigma.) of all steels tested s ) Sharply decreases in the range of 500-600 deg.C, and has a sigma at 700 deg.C or above 700 deg.C s The pressure is reduced to below 50 MPa. If the temperature for securing strength is set to 700 ℃, a large amount of alloying elements must be added, which makes it difficult to secure good weldability and also greatly increases the cost. If the temperature for ensuring the strength is set at a lower temperature of 500 ℃, the thickness of the refractory coating can be only slightly reduced, which is not in accordance with the original purpose of using refractory weathering steel. Therefore, the fire resistance temperature of the fire resistant weathering steel was set to 600 ℃.
In view of the above, and in accordance with the general requirements of the construction steel, the performance indexes of the fire-resistant weathering steel are determined as follows:
(1) Fire resistance: sigma s,600℃ ≥(2/3)σ s,20℃ ;
(2) The room temperature mechanical property and other quality indexes meet the requirements of the standard of common construction steel;
(3) Shock resistance: sigma at room temperature s /σ b Less than or equal to 0.8, and the fluctuation range of the yield strength is as small as possible;
(4) The weldability is good, equal to or better than that of common construction steel;
(5) Weather resistance: compared with Q345B, the relative corrosion rate is less than or equal to 60 percent by adopting the standard TB/T2375-1993 measurement.
The high-strength fire-resistant weather-resistant steel plate/strip is produced by adopting a strip continuous casting process, and due to the sub-rapid solidification characteristic of the strip continuous casting process, a fine crystal layer with a certain thickness can be naturally formed on the surface of the strip steel, so that the produced steel has weather resistance; meanwhile, the novel LED lamp has certain manufacturing and cost advantages in thin-specification use occasions. The specification characteristic thickness of the thin-specification high-strength fire-resistant weather-resistant steel plate/strip is 1.2-2.0mm, and because the thickness of the product is thinner, if the traditional continuous casting and hot continuous rolling production line is adopted for production, the production is difficult, even if the thin slab continuous casting and rolling production is adopted, the roller consumption of a roller is larger, and the production cost of the thin-specification high-strength fire-resistant weather-resistant steel plate/strip is increased by the production process.
When the hot-rolled strip steel is used as a thin hot-rolled plate product, the requirement on the surface quality of the strip steel is high. It is generally required that the thinner the scale on the surface of the strip, the better the scale formation is, and it is necessary to control the scale formation in the subsequent stages of the strip casting, for example, in a typical process, a closed chamber device is used from the crystallizing roll to the rolling mill entrance to prevent the oxidation of the strip casting, and the thickness of the scale on the surface of the strip casting can be controlled by adding hydrogen gas into the closed chamber device, for example, in US6920912 and controlling the oxygen content to be less than 5% in US 20060182989. However, there are few patents on how to control the thickness of the scale during the transport from the rolling mill to the coiling, and particularly, in the cooling of the strip by laminar cooling or spray cooling, the strip at high temperature is in contact with cooling water, and the scale thickness on the surface of the cast strip increases rapidly. Meanwhile, the contact between the high-temperature strip steel and the cooling water also brings about a plurality of problems: firstly, water spots (rusty spots) are formed on the surface of strip steel, and the surface quality is influenced; secondly, cooling water for laminar cooling or spray cooling easily causes uneven local cooling on the surface of the strip steel and uneven microstructure inside the strip steel, thereby causing uneven performance of the strip steel and influencing product quality; thirdly, the local cooling of the surface of the strip steel is uneven, which causes the deterioration of the plate shape and influences the quality of the plate shape.
However, the continuous strip casting has the fast solidification process characteristics, so that the produced steel generally has the problems of uneven structure, low elongation, high yield ratio and poor formability; meanwhile, the austenite grains of the cast strip have obvious nonuniformity, which can cause the structure of a final product obtained after austenite phase transformation to be nonuniform, thereby causing the instability of the performance, particularly the forming performance, of the product. Therefore, the high-strength fire-resistant weather-resistant steel plate/strip product produced by adopting the thin-strip continuous casting process has certain difficulty and challenge, and needs to make a breakthrough in composition and process.
Chinese patent CN200610123458.1 discloses a method for producing 700MPa grade high strength weathering steel by Ti micro alloying process based on thin slab continuous casting and rolling process, the chemical components of the weathering steel plate manufactured by the method are: c:0.03 to 0.07%, si:0.3-0.5%, mn:1.2-1.5, P: less than or equal to 0.04 percent, S: less than or equal to 0.008 percent, al:0.025-0.05%, cr:0.3-0.7%, ni:0.15-0.35%, cu:0.2-0.5%, ti:0.08-0.14%, N: less than or equal to 0.008 percent, and the balance of Fe and inevitable impurities. The yield strength of the steel plate is more than or equal to 700MPa, the tensile strength is more than or equal to 775MPa, and the elongation is more than or equal to 21 percent. In the patent, the phosphorus is controlled according to impurity elements, the content is less than or equal to 0.04 percent, and is less than or equal to 0.025 percent compared with the traditional process, so that the phosphorus content is relaxed.
Chinese patent CN200610035800.2 discloses a method for producing 700MPa V-N microalloying weathering steel based on a thin slab continuous casting and rolling process, and the chemical components of the weathering steel plate manufactured by the method are as follows: c: less than or equal to 0.08 percent, si:0.25-0.75%, mn:0.8-2, P: less than or equal to 0.07-0.15 percent, S: less than or equal to 0.04 percent, cr:0.3-1.25%, ni: less than or equal to 0.65%, cu:0.25-0.6%, V:0.05-0.2%, N:0.015 to 0.03 percent, and the balance of Fe and inevitable impurities. The yield strength of the steel plate is more than or equal to 700MPa, the tensile strength is more than or equal to 785MPa, and the elongation is more than or equal to 21%. In this patent, phosphorus is controlled according to elements for improving weather resistance, and the content is 0.07-0.15%; the copper content is 0.25-0.6%, and the lower limit and the upper limit are respectively 0.2% and 0.55% higher than the lower limit and the upper limit of the copper content of the traditional process.
Chinese patent CN1633509A discloses a method for producing copper-containing carbon steel products by strip casting, which emphasizes that the strip is subjected to heat treatment processes such as annealing and tempering at 400-700 ℃ to precipitate or recrystallize copper elements in the strip. The manufacturing method of the high-copper low-alloy thin strip mentioned in the US patent 2008264525/CN200580009354.1 is technically characterized in that the strip steel is cooled to be lower than 1080 ℃ in a non-oxidizing atmosphere before entering a rolling mill so as to prevent the strip steel from generating the phenomenon of hot brittleness.
These patents all relate to the weather resistance of steel, but do not relate to the effect of fire resistance, and the present invention is a steel grade specifically proposed for the fire and weather resistance characteristics.
Disclosure of Invention
The invention aims to provide a high-strength fire-resistant weather-resistant steel plate/belt and a production method thereof, the produced fire-resistant weather-resistant steel plate/belt can ensure that steel keeps higher strength level at high temperature, the quality of a building can be reduced, the safety of the building is improved, and the construction cost is reduced; meanwhile, by utilizing the technological characteristics of thin strip continuous casting, the produced fire-resistant weather-resistant steel plate/strip naturally forms a fine crystal layer with a certain thickness on the surface of the strip steel on the basis of the fire resistance, so that the product has weather resistance. The product has excellent earthquake resistance and excellent fire resistance, is an ideal material in the field of steel for earthquake resistance and fire prevention, can be widely applied to industries and fields of construction steel with fireproof and earthquake resistance requirements, tower and mast column, engineering machinery, industrial structures and the like, and is particularly applied to places with higher fire safety requirements such as high-rise buildings, large public buildings, high-grade houses and the like.
In order to achieve the purpose, the technical scheme of the invention is as follows:
the invention selectively adds Mo/Nb/Cr microalloy elements and B elements in the steel; in the smelting process, the alkalinity of slag, the type and melting point of inclusions in steel, the free oxygen content in molten steel and the content of acid-soluble aluminum Als are controlled; then, performing double-roller thin-strip continuous casting to cast strip steel with the thickness of 1.5-3mm, directly entering a lower closed chamber with non-oxidizing atmosphere after the strip steel exits from a crystallization roller, and entering an online rolling mill for hot rolling under the closed condition; the rolled strip steel is cooled by adopting an air atomization cooling mode, and the air atomization cooling mode can effectively reduce the thickness of oxide skins on the surface of the strip steel, improve the temperature uniformity of the strip steel and improve the surface quality of the strip steel. The finally produced steel coil can be directly used as a hot rolled plate/strip, and can also be used as a finishing plate/strip after edge cutting and flattening. The material has low yield ratio, excellent earthquake resistance and excellent fire resistance, and is an ideal material in the field of steel for earthquake resistance and fire prevention.
Specifically, the high-strength fire-resistant weather-resistant steel plate/belt comprises the following components in percentage by weight: c:0.02 to 0.06%, si:0.1-0.55%, mn:0.4-1.7%, P is less than or equal to 0.03%, S is less than or equal to 0.007%, cr:0.30-0.80%, cu:0.10-0.60%, mo:0.20-0.60%, nb:0.01-0.08%, N:0.004-0.010% of Als<0.001%, B:0.001-0.006% of total oxygen [ O ]] T :0.007-0.020%; the balance of Fe and inevitable impurities; and, simultaneously:
Mn/S>250;
Pcm≤0.27%,Pcm=C+Si/30+Mn/20+Cu/20+Cr/20+Mo/15+5B。
the microstructure of the high-strength fire-resistant weather-resistant steel plate/belt is a mixed microstructure of block ferrite, pearlite and acicular ferrite or a mixed microstructure of block ferrite, pearlite and lower bainite.
The room temperature yield strength of the high-strength fire-resistant weather-resistant steel plate/belt is more than or equal to 410MPa, the tensile strength is more than or equal to 590MPa, and the elongation is more than or equal to 17 percent; yield ratio sigma s /σ b Less than or equal to 0.8; the yield strength at 600 ℃ is more than or equal to 275MPa and sigma s,600℃ /σ s,20℃ Not less than 0.67; the relative corrosion rate is less than or equal to 60 percent.
In the composition design of the steel of the invention:
the high-strength fire-resistant weather-resistant steel plate/belt comprises the following chemical components in percentage by weight: c:0.02-0.06%, si:0.1-0.55%, mn:0.4-1.7%, P is less than or equal to 0.03%, S is less than or equal to 0.007%, cr:0.30-0.80%, cu:0.10-0.60%, mo:0.20-0.60%, nb:0.01-0.08%, N:0.004-0.010% of Als<0.001%, B:0.001-0.006% of total oxygen [ O ]] T :0.007-0.020%; the balance being Fe and unavoidable impurities.
The reasons for limiting the chemical composition of the high-strength fire-resistant weather-resistant steel plate/belt according to the present invention are as follows:
c: c is the most economical and basic strengthening element in steel, and enhances the strength of steel by solid solution strengthening and precipitation strengthening. C is an essential element for precipitating cementite during austenite transformation, so the strength level of the steel is determined to a great extent by the content of C, namely, higher C content corresponds to higher strength level. However, since interstitial solid solution and precipitation of C greatly impair the plasticity and toughness of steel, and an excessively high C content is disadvantageous in weldability, the C content cannot be excessively high, and the strength of steel is compensated by appropriate addition of alloy elements. Meanwhile, for conventional slab continuous casting, casting in a peritectic reaction region is easy to generate surface cracks of a casting blank, and a steel leakage accident can happen in severe cases. The same is true for thin strip casting, where casting a cast strip in the peritectic reaction zone is prone to surface cracking and, in severe cases, strip breakage. Therefore, strip casting of Fe — C alloys also requires avoidance of the peritectic reaction zone. Therefore, the content range of C adopted by the invention is 0.02-0.06%.
Si: si acts as a solid solution strengthening in steel, and addition of Si to steel improves steel purity and deoxidation, but too high a Si content results in deterioration of weldability and toughness of weld heat affected zone. Therefore, the Si content range adopted by the invention is 0.1-0.55%.
Mn: mn is one of the cheapest alloy elements, can improve the hardenability of steel, has considerable solid solubility in the steel, improves the strength of the steel through solid solution strengthening, basically has no damage to the plasticity and the toughness of the steel, is the most main strengthening element for improving the strength of the steel, and can play a role in deoxidizing in the steel. However, too high a Mn content results in deterioration of weldability and toughness of weld heat-affected zone. Therefore, the Mn content range adopted by the invention is 0.4-1.7%.
P: high content of P is easy to be segregated in grain boundary, increases cold brittleness of steel, deteriorates welding performance, reduces plasticity and deteriorates cold bending performance. In the thin strip continuous casting process, the solidification and cooling rates of the cast strip are extremely high, and the segregation of P can be effectively inhibited, so that the disadvantages of P can be effectively avoided, and the advantages of P can be fully exerted. Therefore, in the invention, the P content is higher than that in the traditional process, the content of the P element is properly relaxed, the dephosphorization procedure is eliminated in the steelmaking procedure, in the actual operation, the dephosphorization procedure is not required to be carried out intentionally, no extra phosphorus is required to be added, and the range of the P content is less than or equal to 0.03 percent.
S: in general, S is a harmful element in steel, causes hot brittleness of steel, reduces ductility and toughness of steel, and causes cracks during rolling. S also reduces weldability and corrosion resistance. Therefore, in the present invention, S is also controlled as an impurity element, and the content range thereof is 0.007% or less. And Mn/S >250.
And Als: in order to control inclusions in steel, the invention requires that Al cannot be used for deoxidation, and in the use of refractory materials, the additional introduction of Al is avoided as much as possible, and the content of acid-soluble aluminum Als is strictly controlled: <0.001%.
N: similar to C element, N element can improve the strength of steel through interstitial solid solution, and the invention needs to generate a BN precipitated phase by utilizing the action of N and B in the steel and needs a certain content of N in the steel. However, the interstitial solid solution of N has great harm to the plasticity and toughness of the steel, and the existence of free N can improve the yield ratio of the steel, so that the content of N cannot be too high. The content range of N adopted by the invention is 0.004-0.010%.
Cr: the Cr is added into the fire-resistant weathering steel, so that the high-temperature strength and creep strength of the steel are improved, the weather resistance of the steel is improved, and the corrosion resistance of the steel can be obviously improved. However, the welding property is seriously deteriorated by too high a content thereof, and the Cr content is limited to 0.30 to 0.80% in the present invention.
Nb: in the refractory steel, nb is mainly used to improve the high-temperature strength of the steel by precipitation strengthening of NbC in ferrite. Meanwhile, in the strip casting process, due to the unique characteristics of rapid solidification and rapid cooling, the added alloy element Nb can exist in the steel strip in a solid solution state more, and the Nb element in the steel in the solid solution state can play a role in solid solution strengthening. The content range of Nb designed by the invention is 0.01-0.08%.
Mo: the solid solution in the ferrite strengthens the ferrite matrix, and the diffusion speed of Mo in the ferrite is slow at high temperature, so that the high-temperature strength and creep strength of the steel can be obviously improved. Research shows that the solid-dissolved Mo is easy to segregate on the grain boundary, and plays a role in improving the high-temperature strength of the steel; mo can also increase the stability of super-cooled austenite, and the volume fraction of bainite in steel is increased after Mo is added; the bainite structure with high dislocation density enables the fire-resistant weathering steel to obtain good high-temperature performance. Mo precipitates in steel to form carbide, which improves the high-temperature strength of the steel. Research shows that better precipitation strengthening effect can be generated after Nb and Mo are added in a composite way: the 1 st view is that in the composite addition, in addition to the strengthening effect of adding Nb and Mo separately, mo can be enriched on an NbC/matrix interface, so that the coarsening of NbC particles is prevented, and the high-temperature strength of the steel is further improved; the 2 nd view shows that Mo reduces the precipitation driving force of NbC and obstructs the diffusion nucleation process of the NbC, thereby delaying the precipitation of the NbC, and Mo in steel promotes bainite transformation, so that the dislocation density of the steel is increased, and the nucleation position of the NbC is increased. These result in a better precipitation strengthening effect, which in turn improves the high temperature strength of the steel. Too high Mo increases the raw material smelting cost of the steel. Therefore, the content range of Mo designed by the invention is 0.20-0.60%.
Cu: the Cu is also an element for improving weather resistance, and the Cu is an easily segregated element, so that the Cu content is generally strictly controlled in the traditional process flow. By applying the rapid solidification effect of strip casting, the invention improves the upper limit of Cu to 0.60 percent. The improvement of the Cu content can fully utilize the scrap steel in a certain sense, and screening can be omitted when the scrap steel raw material is prepared, so that the smelting operation rate is improved, the cost is reduced, the recycling of the steel is promoted, and the purpose of sustainable development is realized; and the effective utilization of copper in poor-quality ore resources (such as high copper ore) can be realized.
B: the significant role of B in steel is: the hardenability of the steel can be multiplied by trace boron, B can preferentially precipitate coarse BN particles in high-temperature austenite to inhibit the precipitation of fine AlN, weaken the pinning effect of the fine AlN on grain boundaries, improve the growth capability of grains, coarsen and homogenize austenite grains, facilitate the recrystallization after rolling, and reduce the yield ratio sigma of products after coarsening and homogenizing the austenite grains s /σ b The fluctuation range of the yield strength is reduced, and the anti-seismic performance is improved; in addition, the combination of B and N can effectively prevent the grain boundary low melting point phase B 2 O 3 Is present.
B isActive and easily segregated elements are easy to segregate in a crystal boundary, and the content of B is generally controlled to be very strict and is generally about 0.001-0.003 percent when B-containing steel is produced by the traditional process; in the thin strip continuous casting process, the solidification and cooling rates are high, the segregation of B can be effectively inhibited, and the content of B is more in solid solution, so that the content of B can be properly widened; and coarse BN particles can be generated through reasonable process control, and the precipitation of fine AlN is inhibited, so that the nitrogen fixation effect is realized. It is also shown that B, when added in combination with Nb and Mo, produces better effects, reduces the tendency of segregation of C atoms and avoids grain boundary Fe 23 (C,B) 6 So that more B can be added. Therefore, in the present invention, a higher B content is used than in the conventional process, in the range of 0.001-0.006%.
In order to ensure the welding performance of the steel grade, the following relational expression is satisfied when the elements are designed: pcm is less than or equal to 0.27%, pcm = C + Si/30+ Mn/20+ Cu/20+ Cr/20+ Mo/15+5B.
The production method of the high-strength fire-resistant weather-resistant steel plate/belt comprises the following steps:
a) Smelting of
Smelting according to the chemical composition requirement, wherein the alkalinity a = CaO/SiO of slagging in the steelmaking process 2 Control in a<1.5, preferably a<1.2, or a =0.7-1.0; obtaining low melting point MnO-SiO in molten steel 2 -Al 2 O 3 MnO/SiO in ternary inclusions 2 Controlling the concentration to be 0.5-2, preferably 1-1.8; free oxygen [ O ] in molten steel] Free The contents are as follows: 0.0005 to 0.005 percent; in the molten steel composition, mn/S>250;
b) Continuous casting
The continuous casting adopts double-roller thin strip continuous casting, and a casting strip with the thickness of 1.5-3mm is formed at the position with the minimum gap between two crystallizing rollers; the diameter of the crystallization roller is 500-1500mm, and the preferred diameter is 800mm; cooling the crystallization roller by introducing water, wherein the casting speed of the casting machine is 60-150m/min; a two-stage steel water distribution system is adopted for continuous casting flow distribution, namely a tundish and a flow distributor;
c) Lower enclosed chamber protection
After the casting strip is taken out of the crystallization roller, the casting strip is directly fed into a lower closed chamber at the temperature of 1420-1480 ℃, non-oxidizing gas is introduced into the lower closed chamber, the oxygen concentration in the lower closed chamber is controlled to be less than 5 percent, and the temperature of the casting strip at the outlet of the lower closed chamber is 1150-1300 ℃;
d) In-line hot rolling
Conveying the cast strip to a rolling mill in a lower closed chamber through a pinch roll, and rolling the cast strip into strip steel with the thickness of 0.8-2.5mm, wherein the rolling temperature is 1100-1250 ℃, the hot rolling reduction is controlled to be 10-50%, and the preferred hot rolling reduction is 30-50%; the thickness of the rolled strip steel is 0.8-2.5mm, and the preferred thickness is 1.2-2.0mm;
e) Strip steel cooling after rolling
Cooling the rolled strip steel after rolling, and cooling the strip steel by adopting an air atomization cooling mode, wherein the cooling rate range of air atomization cooling is 20-100 ℃/s;
f) Strip steel coiling
And cutting the head of the cooled hot-rolled strip steel by using a cutting head to remove the head with poor quality, and directly coiling the hot-rolled strip steel into coils at the coiling temperature of 500-600 ℃.
Further, g) subsequent treatment, wherein the steel coil is directly used as a hot rolled plate/strip or used as a finishing plate/strip after edge cutting and flattening.
Preferably, in step c), the non-oxidizing gas comprises: n is a radical of 2 Ar, or CO obtained by sublimation on dry ice 2 A gas.
Preferably, in the step e), the gas-water ratio of the gas atomization cooling is 15:1 to 10:1, the air pressure is 0.5-0.8 MPa, and the water pressure is 1.0-1.5 MPa.
Preferably, in step f), the coiling is in the form of a twin coiler or in the form of a carrousel coiler.
In the production method of the present invention:
the smelting is carried out by electric furnace steelmaking or converter steelmaking, and then the steel is refined in an LF furnace, a VD/VOD furnace or an RH furnace.
In order to improve the castability of the strip-cast molten steel, the basicity of the slagging in the steel-making process a = CaO/SiO 2 Is controlled at a<1.5, preferably a<1.2, or a =0.7-1.0.
To improve the castability of thin strip continuous casting molten steel, it is necessary to obtain MnO-SiO of low melting point 2 -Al 2 O 3 Ternary inclusions, e.g. shaded areas of FIG. 2, mnO-SiO 2 -Al 2 O 3 MnO/SiO in ternary inclusions 2 The content is controlled to be 0.5 to 2, preferably 1 to 1.8.
In order to improve the castability of thin strip cast molten steel, oxygen (O) in the steel is an essential element for forming oxide inclusions, and the present invention requires formation of MnO-SiO with a low melting point 2 -Al 2 O 3 The ternary inclusions of (2) require free oxygen [ O ] in molten steel] Free The range is as follows: 0.0005-0.005%.
After the cast strip is taken out of the crystallization roller, the cast strip is directly fed into a lower closed chamber at the temperature of 1420-1480 ℃, the non-oxidizing gas is introduced into the lower closed chamber to protect the strip steel, and the oxidation prevention protection of the strip steel is realized in an atmosphere of N 2 Ar, or other non-oxidizing gas, such as CO obtained by sublimation of dry ice 2 Gas, etc., the oxygen concentration in the lower sealed chamber is controlled<5 percent. The lower closed chamber protects the cast strip from oxidation to the mill inlet. The temperature of the cast strip at the outlet of the lower closed chamber is 1150-1300 ℃.
The theoretical basis of BN precipitated phase involved in the lower sealing process of the cast strip is as follows:
the thermodynamic equations of boron with nitrogen, aluminum and nitrogen in gamma-Fe in steel are as follows:
BN=B+N;Log[B][N]=-13970/T+5.24 (1)
AlN=Al+N;Log[Al][N]=-6770/T+1.03 (2)
as shown in FIG. 3, the initial precipitation temperature of BN in the steel is about 1280 ℃ and the precipitation of BN at 980 ℃ is in equilibrium, but the precipitation of AlN is just started (the precipitation temperature of AlN is about 980 ℃), and the precipitation of BN is thermodynamically preferred to AlN. The invention completes the combination of B and N in the lower closed chamber to generate coarse BN particles, thereby inhibiting the precipitation of fine AlN, weakening the pinning effect of the fine AlN on grain boundaries, improving the growth capability of crystal grains, coarsening austenite crystal grains, leading the austenite crystal grains to be more uniform and being beneficial to reducing the yield ratio sigma of products s /σ b The fluctuation range of the yield strength is reduced, and the anti-seismic performance is improved; in addition, the combination of B and N can effectively prevent the grain boundary from being lowMelting point phase B 2 O 3 Of the cell.
The strip steel after the online hot rolling is cooled after being rolled, the rolled strip steel is cooled by adopting an air atomization cooling mode, and the air atomization cooling mode can effectively reduce the thickness of oxide scale on the surface of the strip steel, improve the temperature uniformity of the strip steel and improve the surface quality of the strip steel. The gas-water ratio of gas atomization cooling is 15:1 to 10:1, the air pressure is 0.5-0.8 MPa, and the water pressure is 1.0-1.5 MPa. High-pressure water mist is formed after gas atomization and sprayed on the surface of the steel strip, so that on one hand, the temperature of the steel strip is reduced, on the other hand, the water mist can form a compact air film to be coated on the surface of the steel strip, the anti-oxidation effect of the steel strip is achieved, and the growth of oxide skin on the surface of the hot-rolled steel strip is effectively controlled. The cooling mode can avoid the problems brought by the traditional spraying or laminar cooling, so that the surface temperature of the strip steel is uniformly reduced, and the temperature uniformity of the strip steel is improved, thereby achieving the effects of homogenizing the internal microstructure and improving the yield ratio of materials; meanwhile, the cooling is uniform, so that the shape quality and the performance stability of the strip steel can be improved; effectively reducing the thickness of the oxide scale on the surface of the strip steel. The cooling rate of the gas atomization cooling is in the range of 20-100 ℃/s.
And cutting the head of the cooled hot-rolled strip steel to remove the head with poor quality, and directly coiling the hot-rolled strip steel into coils. The coiling temperature of the hot rolled strip was controlled to 500-600 ℃, and the high temperature austenite structure after rolling was transformed into a mixed microstructure of bulk ferrite + pearlite + acicular ferrite, or a mixed microstructure of bulk ferrite + pearlite + lower bainite, as shown in fig. 4. The coiler adopts a double-coiling form and a carrousel coiling form to ensure the continuous production of the strip steel.
Through the manufacturing process, the performance of the final high-strength fire-resistant weather-resistant steel plate/belt can reach: the yield strength at room temperature is more than or equal to 410MPa, the tensile strength is more than or equal to 590MPa, and the elongation is more than or equal to 17 percent; yield ratio sigma s /σ b Less than or equal to 0.8; the yield strength at 600 ℃ is more than or equal to 275MPa and sigma s,600℃ /σ s,20℃ Not less than 0.67; the relative corrosion rate is less than or equal to 60 percent.
The invention has the main advantages that:
the invention uses the thin strip continuous casting technology to produce the boron (B) -containing high-strength fireproof weathering steel, has no report so far, and has the following advantages:
1. the invention omits the complex processes of slab heating, multi-pass repeated hot rolling and the like, and has the advantages of shorter production flow, higher efficiency and greatly reduced investment cost and production cost of the production line through the working procedures of double-roller thin-strip continuous casting and one-pass online hot rolling.
2. The invention omits a plurality of complex intermediate steps in the production of the traditional process, and compared with the traditional production process, the energy consumption and CO of the production are reduced 2 Greatly reduces the emission, and is a green and environment-friendly product.
3. The invention adopts the thin strip continuous casting process to produce the hot-rolled thin high-strength fire-resistant weathering steel, and because of the sub-rapid solidification characteristic of the thin strip continuous casting process, a fine crystal layer with a certain thickness can be naturally formed on the surface of the strip steel, so that the produced steel grade has weather resistance; meanwhile, the thickness of the cast strip is thin, and the thin-specification product can be directly supplied to the market for use by online hot rolling to the desired product thickness, so that the purpose of supplying the thin-specification hot rolled plate is achieved, and the cost performance of the plate strip can be obviously improved.
4. According to the invention, trace B element is added, and coarse BN particles are preferentially precipitated in high-temperature austenite, so that the precipitation of fine AlN is inhibited, the pinning effect of fine AlN on grain boundaries is weakened, the growth capability of grains is improved, austenite grains are coarsened and homogenized, the yield ratio of the material is favorably reduced, the low yield ratio is favorable for improving the energy absorption of a building structure during earthquake, and the anti-seismic performance of the material is improved.
5. Because the scrap steel contains Cu, the scrap steel can be fully utilized, the existing scrap steel or low-quality inferior ore resources (high tin ore and high copper ore) can be fully utilized, the recycling of the scrap steel is promoted, the production cost is reduced, and the sustainable development of the steel industry is realized.
6. The air atomization cooling mode of the rolled strip steel is adopted, so that the problems caused by the traditional spraying or laminar cooling can be avoided, the surface temperature of the strip steel is uniformly reduced, the temperature uniformity of the strip steel is improved, and the effect of homogenizing the internal microstructure is achieved; meanwhile, the cooling is uniform, so that the shape quality and the performance stability of the strip steel can be improved; effectively reducing the thickness of oxide scale on the surface of the strip steel.
7. In the traditional process, alloy elements are separated out in the cooling process of the plate blank, and the utilization rate of the alloy elements is reduced because the re-dissolution of the alloy elements is insufficient when the plate blank is reheated. In the thin strip continuous casting process, the high-temperature cast strip is directly hot-rolled, and the added alloy elements mainly exist in a solid solution state, so that the alloy utilization rate can be improved.
8. According to the invention, the hot rolled steel strip carrousel coiling machine is selected, so that the length of a production line is effectively shortened; meanwhile, the control precision of the coiling temperature can be greatly improved by the co-position coiling, and the stability of the product performance is improved.
9. The most obvious characteristic of the invention which is different from the prior thin strip continuous casting technology is the roller diameter of the crystallization roller and the corresponding flow distribution mode. The EUROSTRIP technology is characterized in that the crystallization roller with a large roller diameter of 1500mm phi is large, the molten steel capacity of a molten pool is large, the distribution is easy, and the manufacturing cost and the operation cost of the crystallization roller are high. The CASTIP technology is characterized in that a crystallization roller with a small roller diameter of 500mm phi is small, the molten steel capacity of a molten pool is small, the distribution is very difficult, but the manufacturing, operation and maintenance costs of casting machine equipment are low.
CASTRIP adopts a three-stage molten steel distribution system (tundish, transition ladle and distributor) to solve the problem of uniform distribution of small molten pools. Due to the adoption of a three-stage flow distribution system, the cost of refractory materials is directly increased; more importantly, the three-stage flow distribution system enables the flowing path of the molten steel to be lengthened, the temperature drop of the molten steel to be larger, and in order to meet the temperature of the molten steel in a molten pool, the tapping temperature needs to be greatly improved. The increase of the tapping temperature causes problems such as increase of steel-making cost, increase of energy consumption, and shortening of the life of refractory.
10. The diameter of the crystallization roller is 500-1500mm, preferably the diameter of the roller is 800mm, and a two-stage steel water distribution system (a tundish and a flow distributor) is adopted. Molten steel flowing out of the flow distributor forms different flow distribution modes along the roller surface and the two end surfaces, and flows in two paths without mutual interference. Because a two-stage flow distribution system is adopted, compared with a three-stage flow distribution system, the cost of the refractory material is greatly reduced; the reduction of the flow path of the molten steel reduces the temperature drop of the molten steel, and can reduce the tapping temperature by 30-50 ℃ compared with a three-level flow distribution system. The reduction of the tapping temperature can effectively reduce the steel-making cost, save the energy consumption and prolong the service life of refractory materials. The invention is matched with the crystallization roller with the optimal roller diameter of phi 800mm, and adopts a two-stage steel water distribution system, thereby not only realizing the requirement of stable distribution of molten steel, but also realizing the aims of simple structure, convenient operation and low processing cost.
Drawings
FIG. 1 is a schematic layout of a twin roll strip casting process;
FIG. 2 shows MnO-SiO 2 -Al 2 O 3 Ternary phase diagram (shaded area: low melting point region);
FIG. 3 is a schematic diagram of a thermodynamic curve of BN, alN precipitation;
FIG. 4 is a photograph of the microstructure of the steel according to the example of the present invention.
Detailed Description
The invention is further illustrated below by means of examples and figures, which are not intended to limit the invention in any way. Any variations in the practice of the invention that may occur to those skilled in the art and which are made in the light of the teachings of this specification are intended to be within the scope of the following claims.
Referring to fig. 1, molten steel designed according to the chemical composition of the present invention is directly poured through a ladle 1 through a ladle shroud 2, a tundish 3, a submerged nozzle 4 and a distributor 5 into a molten pool 7 surrounded by two counter-rotating and rapidly-cooled crystallization rolls 8a, 8b and side closing plate devices 6a, 6b, and the molten steel is solidified on the circumferential surfaces of the rotation of the crystallization rolls 8a, 8b to form solidified shells and gradually grow, and then a cast strip 11 with a thickness of 1.5-3mm is formed at the minimum clearance (nip point) between the two crystallization rolls. The diameter of the crystallization roller is 500-1500mm, and water is introduced into the crystallization roller for cooling. The casting speed of the casting machine is 60-150m/min according to different thicknesses of the cast strip.
After the cast strip 11 comes out of the crystallization rollers 8a and 8b, the cast strip is directly fed into the lower closed chamber 10 at 1420-1480 ℃, the non-oxidizing gas is introduced into the lower closed chamber 10 to protect the strip steel, so as to realize the anti-oxidation protection of the strip steel, and the atmosphere of the anti-oxidation protection can be N 2 Ar, or other non-oxidizing gas, such as CO obtained by sublimation of dry ice 2 Gas, etc., the oxygen concentration in the lower sealed chamber 10 is controlled to be<5 percent. Lower enclosed chamber 10 protects against oxidation of cast strip 11 to the entrance of rolling mill 13. The temperature of the cast strip at the outlet of the lower closed chamber 10 is 1150-1300 ℃. Then the cast strip is sent to a hot rolling mill 13 through a swinging guide plate 9 and a pinch roll 12, a hot rolled strip with the thickness of 0.8-2.5mm is formed after hot rolling, and the rolled strip steel is cooled by adopting an air atomization cooling mode, so that the temperature uniformity of the strip steel is improved. After the head is cut by the flying shear device 16, the head falls into the flying shear pit 18 along the flying shear guide plate 17, and the hot rolled strip after the head is cut enters the coiler 19 for coiling. And taking the steel coil off the coiling machine, and naturally cooling to room temperature. The finally produced steel coil can be directly used as a hot rolled plate/strip, and can also be used as a finishing plate/strip after edge cutting and flattening.
The process of the invention is further illustrated by the examples. The chemical compositions of the examples of the present invention are shown in table 1, and the balance of the compositions is Fe and other unavoidable impurities. The production method and the technological parameters are shown in the table 2, and the mechanical properties of the finally obtained hot rolled strip are shown in the table 3.
The corrosion resistance of the example steels was tested: a72 h period infiltration cycle corrosion test is carried out according to a 72h period infiltration corrosion test method (TB/T2375-1993) by taking a common carbon steel Q345B as a comparison sample. And calculating the corrosion weight loss of the sample in unit area to obtain the average corrosion rate and further obtain the relative corrosion rate of the steel grade. The test results are shown in Table 4.
In conclusion, the high-strength fire-resistant weather-resistant steel plate/strip produced by the strip continuous casting process technology according to the design range of the steel grade components provided by the invention has the room-temperature yield strength of more than or equal to 410MPa, the tensile strength of more than or equal to 590MPa and the elongation of more than or equal to 17 percent; yield ratio sigma s /σ b Less than or equal to 0.8; the yield strength at 600 ℃ is more than or equal to 275MPa and sigma s,600℃ /σ s,20℃ Not less than 0.67; and the cold-processing bending performance is qualified.
The comparison result of the corrosion resistance also shows that the relative corrosion rate of the steel grade is less than or equal to 60 percent. The material meets and exceeds the performance requirements of fire-resistant and weather-resistant steel, can realize the supply of thin hot-rolled products, greatly reduces the production cost, has low yield ratio of materials, excellent earthquake resistance and excellent fire resistance, and is an ideal material in the field of earthquake-resistant and fire-resistant steel.
Claims (12)
1. A high-strength fire-resistant weather-resistant steel plate/belt comprises the following components in percentage by weight: c:0.02 to 0.06%, si:0.1-0.55%, mn:0.4-1.7%, P is less than or equal to 0.03%, S is less than or equal to 0.007%, cr:0.30-0.80%, cu:0.10-0.60%, mo:0.20-0.60%, nb:0.01-0.08%, N:0.004-0.010% of Als<0.001%, B:0.001-0.006% of total oxygen [ O ]] T The content is as follows: 0.007 to 0.020 percent, and the balance of Fe and inevitable impurities; and, simultaneously:
Mn/S>250;
pcm is less than or equal to 0.27%, pcm = C + Si/30+ Mn/20+ Cu/20+ Cr/20+ Mo/15+5B; and are
Obtained by a process comprising the steps of:
a) Smelting of
Smelting according to the chemical composition requirements, wherein the slagging alkalinity a = CaO/SiO in the steelmaking process 2 Control at a =0.7-1.0; obtaining low melting point MnO-SiO in molten steel 2 -Al 2 O 3 MnO/SiO in ternary inclusions 2 Controlling the temperature to be 0.5-2; free oxygen [ O ] in molten steel] Free The contents are as follows: 0.0005-0.005%; in molten steel composition, mn/S>250;
b) Continuous casting
The continuous casting adopts double-roller thin strip continuous casting, and a casting strip with the thickness of 1.5-3mm is formed at the position with the minimum gap between two crystallizing rollers; the diameter of the crystallization roller is 500-1500 mm; cooling the crystallization roller by introducing water, wherein the casting speed of the casting machine is 60-150m/min; the continuous casting flow distribution adopts a two-stage steel water distribution system, namely a tundish and a flow distributor;
c) Lower sealed chamber protection
After the cast strip is taken out of the crystallization roller, the temperature of the cast strip is 1420-1480 ℃, the cast strip directly enters a lower closed chamber, non-oxidizing gas is introduced into the lower closed chamber, the oxygen concentration in the lower closed chamber is controlled to be less than 5%, and the temperature of the cast strip at the outlet of the lower closed chamber is 1150-1300 ℃;
d) In-line hot rolling
Conveying the cast strip to a rolling mill in a lower closed chamber through a pinch roll, and rolling the cast strip into strip steel with the thickness of 0.8-2.5mm, wherein the rolling temperature is 1100-1250 ℃, and the hot rolling reduction rate is controlled to be 10-50%; the thickness of the rolled strip steel is 0.8-2.5mm;
e) Strip steel cooling after rolling
Cooling the rolled strip steel after rolling, and cooling the strip steel by adopting an air atomization cooling mode, wherein the cooling rate range of air atomization cooling is 20-100 ℃/s;
f) Strip steel coiling
And cutting the head of the cooled hot-rolled strip steel to remove the head with poor quality, and directly coiling the hot-rolled strip steel into coils at the coiling temperature of 500-600 ℃.
2. A high-strength fire-resistant weather-resistant steel plate/belt as claimed in claim 1, wherein the microstructure of said steel plate/belt is a mixed microstructure of bulk ferrite + pearlite + acicular ferrite, or a mixed microstructure of bulk ferrite + pearlite + lower bainite.
3. The high-strength fire-resistant weather-resistant steel plate/belt as claimed in claim 1 or 2, wherein the yield strength at room temperature of the high-strength fire-resistant weather-resistant steel plate/belt is not less than 410MPa, the tensile strength is not less than 590MPa, and the elongation is not less than 17%; yield ratio sigma s /σ b Less than or equal to 0.8; the yield strength at 600 ℃ is more than or equal to 275MPa and sigma s,600℃ /σ s,20℃ Not less than 0.67; relative corrosion rate≤60%。
4. A production method of a high-strength fire-resistant weather-resistant steel plate/belt is characterized by comprising the following steps:
a) Smelting
Smelting according to the following chemical composition requirements, wherein the basicity of slagging in the steelmaking process is a = CaO/SiO 2 Control at a =0.7-1.0; obtaining low melting point MnO-SiO in molten steel 2 -Al 2 O 3 MnO/SiO in ternary inclusions 2 Controlling the temperature to be 0.5-2; free oxygen [ O ] in molten steel] Free The contents are as follows: 0.0005-0.005%; in the molten steel composition, mn/S>250;
The high-strength fire-resistant weather-resistant steel plate/belt comprises the following components in percentage by weight: c:0.02-0.06%, si:0.1-0.55%, mn:0.4-1.7%, P is less than or equal to 0.03%, S is less than or equal to 0.007%, cr:0.30-0.80%, cu:0.10-0.60%, mo:0.20-0.60%, nb:0.01-0.08%, N:0.004-0.010% of Als<0.001%, B:0.001-0.006% of total oxygen [ O ]] T The content is as follows: 0.007 to 0.020 percent, and the balance of Fe and inevitable impurities; and, simultaneously:
Pcm≤0.27%,Pcm=C+Si/30+Mn/20+Cu/20+Cr/20+Mo/15+5B;
b) Continuous casting
The continuous casting adopts double-roller thin strip continuous casting, and a casting strip with the thickness of 1.5-3mm is formed at the position with the minimum gap between two crystallizing rollers; the diameter of the crystallization roller is 500-1500 mm; cooling the crystallization roller by introducing water, wherein the casting speed of the casting machine is 60-150m/min; a two-stage steel water distribution system is adopted for continuous casting flow distribution, namely a tundish and a flow distributor;
c) Lower sealed chamber protection
After the casting strip is taken out of the crystallization roller, the casting strip is directly fed into a lower closed chamber at the temperature of 1420-1480 ℃, non-oxidizing gas is introduced into the lower closed chamber, the oxygen concentration in the lower closed chamber is controlled to be less than 5 percent, and the temperature of the casting strip at the outlet of the lower closed chamber is 1150-1300 ℃;
d) In-line hot rolling
Conveying the cast strip to a rolling mill in a lower closed chamber through a pinch roll, and rolling the cast strip into strip steel with the thickness of 0.8-2.5mm, wherein the rolling temperature is 1100-1250 ℃, and the hot rolling reduction rate is controlled to be 10-50%; the thickness of the rolled strip steel is 0.8-2.5mm;
e) Cooling after rolling strip steel
Cooling the rolled strip steel after rolling, and cooling the strip steel by adopting an air atomization cooling mode, wherein the cooling rate range of air atomization cooling is 20-100 ℃/s;
f) Strip steel coiling
And cutting the head of the cooled hot-rolled strip steel by using a cutting head to remove the head with poor quality, and directly coiling the hot-rolled strip steel into coils at the coiling temperature of 500-600 ℃.
5. A method for producing a high strength fire resistant weather resistant steel sheet/strip as claimed in claim 4, further comprising g) a subsequent treatment, wherein the steel coil is directly used as a hot rolled sheet/strip or as a finished sheet/strip after trimming and flattening.
6. The method for producing a high strength fire resistant weathering steel plate/belt as claimed in claim 4, wherein in step c), the non-oxidizing gas includes: n is a radical of 2 Ar, or CO obtained by sublimation on dry ice 2 A gas.
7. The method for producing a high strength fire resistant weather resistant steel sheet/belt as claimed in claim 4, wherein in step e), the gas-water ratio of the gas-atomized cooling is 15:1 to 10:1, the air pressure is 0.5-0.8 MPa, and the water pressure is 1.0-1.5 MPa.
8. A method for producing a high strength fire resistant weather resistant steel sheet/strip as claimed in claim 4, wherein in step f), the coiling is performed in a twin coiler type or a Carrosael coiling type.
9. The method for producing a high strength fire resistant weather resistant steel sheet/strip as claimed in claim 4, wherein in step a), mnO-SiO having a low melting point is obtained in said molten steel 2 -Al 2 O 3 MnO/SiO in ternary inclusions 2 The temperature is controlled to be 1-1.8.
10. A method for producing a high strength fire resistant weather resistant steel sheet/strip as claimed in claim 4, wherein in step b), said crystallizing roller has a diameter of 800mm.
11. A method for producing a high strength fire resistant weather resistant steel sheet/strip as claimed in claim 4, wherein said hot rolling reduction in step d) is in the range of 30 to 50%.
12. The method for producing a high strength fire resistant weather resistant steel sheet/strip as claimed in claim 4, wherein in step d), the thickness of said rolled steel sheet/strip is 1.2-2.0mm.
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CN201910888780.0A CN112522640B (en) | 2019-09-19 | 2019-09-19 | High-strength fire-resistant weather-resistant steel plate/belt and production method thereof |
DE112020004462.9T DE112020004462T9 (en) | 2019-09-19 | 2020-09-15 | REFRACTORY AND WEATHERING RESISTANT STEEL SHEET/STRIP AND METHOD OF MAKING THE SAME |
PCT/CN2020/115284 WO2021052314A1 (en) | 2019-09-19 | 2020-09-15 | Fire-resistant weathering steel plate/strip and manufacturing method therefor |
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