CN114086069A

CN114086069A - Magnesium-containing fine-grain hot-rolled plate strip steel and preparation method thereof

Info

Publication number: CN114086069A
Application number: CN202111383150.1A
Authority: CN
Inventors: 王超; 袁国; 康健; 李振垒; 张元祥; 王洋; 方烽; 王国栋
Original assignee: Northeastern University China
Current assignee: Northeastern University China
Priority date: 2021-03-04
Filing date: 2021-03-04
Publication date: 2022-02-25
Anticipated expiration: 2041-03-04
Also published as: CN113025903A; CN114086069B; CN114032469B; CN113025903B; CN114032469A

Abstract

A magnesium-containing fine-grain hot-rolled plate strip steel and a preparation method thereof belong to the field of steel production. The magnesium-containing fine-grain hot rolled plate strip steel comprises the following components in percentage by mass: c: 0.03-0.25%, Si: 0.05-0.5%, Mn: 0.8-2.0%, P: 0.002-0.03%, S: 0.001-0.03%, Al: 0.003 to 0.07%, Ti: 0.002-0.05%, Mg: 0.001-0.01%, O: 0.001-0.01%, N: 0.003-0.015% and the balance of Fe and inevitable impurities; the magnesium-containing fine-grained hot-rolled sheet strip contains Al₂O₃Inclusions, TiO_xInclusions, TiN inclusions, AlN inclusions, MnS inclusions, MgAl₂O₄Inclusions, and other unavoidable inclusions. The preparation method comprises the following steps: the method optimally designs the components and impurities of the hot rolled plate strip steel, combines the improvement of smelting and rolling processes, realizes the grain size refinement under the high-temperature rolling condition, and further improves the obdurability of steel.

Description

Magnesium-containing fine-grain hot-rolled plate strip steel and preparation method thereof

The application has the application number of 202110238994.0, application date of 2021, 03 month of 04, the name of the invention is: a fine-grained hot-rolled plate strip steel and a preparation method thereof.

Technical Field

The invention belongs to the technical field of steel production, and particularly relates to magnesium-containing fine-grain hot-rolled plate strip steel and a preparation method thereof.

Background

The low-alloy high-strength hot-rolled plate strip steel has wide application in economic and social construction, and the production application of the hot-rolled plate strip steel is developed towards high strength and toughness, low alloy cost and high production efficiency along with the continuous improvement of industrial production technology. There are many methods to improve the strength of steel plate, but the grain refinement can improve the strength and toughness at the same time, and save the alloy addition, so it has wide application in the steel industry.

At present, the hot rolled plate and strip steel generally adopts a micro-alloying and rolling and cooling control process method to achieve the purposes of refining the structure and improving the performance. The controlled rolling and controlled cooling process is generally performed by rolling in an austenite non-recrystallization region, and requires waiting at an intermediate thickness, and rolling deformation with large reduction is completed at a lower temperature.

Patent CN111020375A discloses a V-N microalloyed steel medium plate and a production process thereof, and provides a V-N microalloyed steel medium plate and a production process thereof, which improve the yield of medium plate materials by improving the uniformity of structure. However, the medium plate needs to be rolled at low temperature, and has higher requirements on the reduction of the final rolling pass, thereby influencing the production rhythm.

Patent CN102051525A discloses a method for producing a low-cost Q420qE steel plate for bridge, which is characterized in that a small amount of Nb and Ti alloy is added, and strong water cooling is combined to improve the performance, so as to produce the steel plate for bridge with the thickness of Q420qE grade. However, the finish rolling temperature in the finish rolling stage of the method is 790-830 ℃, the requirement on equipment capacity is high, and the rolling energy consumption is large.

The patent CN103451535A discloses a hot continuous rolling plate strip steel for a 510 MPa-grade automobile beam and a production process thereof, only a small amount of Ti is added, and other precious alloy elements are not added, so that the reduction production of steel types is realized. However, the hot continuous rolling plate strip steel adopts a low-temperature rolling process and a continuous variable speed laminar cooling process, which is not beneficial to the stable control of the production process.

Patent CN200610116673.9 discloses a manufacturing process of a fine grain reinforced carbon structural steel hot rolled sheet, which solves the problem of producing a high-strength hot rolled sheet on a hot continuous rolling mill by using common carbon steel components, and improves the strength of steel through fine grain reinforcement. However, the production process is complicated because the coil box needs to be curled after rough rolling and then the low-temperature finish rolling is performed.

Patent CN106244931A discloses a hot rolled steel sheet with a yield strength of 450MPa and a manufacturing method thereof, wherein Ti is adopted to replace Nb, V and other alloy elements, and proper hot rolling process design is combined, so that the alloy cost is reduced on the premise of ensuring the material performance. But low-temperature controlled rolling and laminar cooling are combined to obtain fine ferrite grains, so that the production efficiency is reduced.

The patent CN107130180A discloses a low-cost Q390 medium-thick plate and a production method thereof, which adopts the design of a C-Mn component system, does not add Nb and Ti microalloy elements and reduces the production cost. But the rolled ultra-fast cooling equipment with strong cooling capacity is adopted for cooling, so that the temperature of the red returning is stably controlled, and the process difficulty and the equipment requirement are improved.

From the prior art, in order to realize grain refinement, a low-temperature controlled rolling method has higher requirements on equipment and process water average, the production efficiency can be reduced, the production cost is increased, and other products are not suitable for rolling in a low-temperature non-recrystallization area. Therefore, rolling in a high-temperature region is an effective way for improving the production process, but austenite grains and transformation structures are coarsened in the process, so that the toughness of the steel is reduced. Therefore, studies have been made on steel materials suitable for high-temperature rolling, which are sufficiently refined in the high-temperature rolling process to improve the structure properties of the steel sheet.

The patent CN1092470A discloses a process for high-temperature recrystallization rolling accelerated cooling of a titanium-treated steel plate to replace medium-low temperature control rolling, which is characterized in that 0.005-0.025 percent of Ti is adopted to treat the steel to form TiN and Ti (CN) precipitation phases to refine grains, high-temperature recrystallization rolling and accelerated cooling are adopted, and the final rolling temperature is required to be controlled at 900-1000 ℃.

Patent CN102828115A discloses a Q345B medium plate and a production method thereof, which is characterized in that vanadium-nitrogen microalloying and high-temperature rolling processes are adopted, VN particles precipitated in the high-temperature rolling process are used for inducing to form intragranular ferrite, and the grain size is refined. The steel is required to have the N content of 0.008-0.018%, the final rolling temperature of 1070-1100 ℃, the cooling rate of 18-22 ℃/s and the final cooling temperature of 650-750 ℃.

The patent CN103343209A discloses a controlled rolling and controlled cooling process for improving the performance of a Q235 steel plate, which is characterized in that a middle temperature waiting link of the steel plate is avoided, high-temperature rolling is directly adopted, the initial rolling temperature is 1000-1100 ℃, the final rolling temperature is controlled at 900-950 ℃, and ultra-fast cooling is immediately carried out after rolling, wherein the cooling speed is more than 100 ℃/s.

Patent CN103966410A discloses a method for producing a Q420-grade thick plate by high-temperature rolling, which is characterized in that VN microalloying component design is adopted, a process of waiting for temperature of an intermediate billet is cancelled in a high-temperature rolling mode, the temperature of rough rolling and finish rolling are both above 1000 ℃, stacking and slow cooling are adopted for cooling after rolling, and the obtained structure is a polygonal ferrite plus pearlite structure.

From the prior art, in order to realize grain refinement, a low-temperature controlled rolling method has higher requirements on equipment and process water average, obviously reduces the production efficiency and increases the production cost. Therefore, it is necessary to solve the above problems, to make innovations in the composition and process technology of hot-rolled steel sheets, shorten the process flow, improve the production efficiency, save resources, and realize low-cost and high-quality production.

The prior art can obtain fine crystalline structures after the rolling temperature is increased to meet the performance requirements, but adopts the method of alloying or ultra-fast cooling immediately after rolling, thereby bringing pressure on the production cost and the technical implementation. If the structure refined particles with good thermal stability are introduced into the steel, the structure refined particles are dispersed and distributed in the steel matrix, the effect of structure refinement is exerted in the rolling process, and the prior production process and the product performance are obviously improved and promoted. However, there is no prior art available to achieve this goal and further research is needed.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides magnesium-containing fine-grain hot-rolled plate strip steel and a preparation method thereof, wherein the fine-grain hot-rolled plate strip steel comprises a hot-rolled steel plate and a hot-rolled steel strip; the method optimally designs the components and the inclusions of the hot rolled plate strip steel, combines the smelting and rolling process improvement, realizes the grain size refinement under the high-temperature rolling condition, and further improves the toughness of the steel. At present, the grain refinement of hot rolled steel is mainly realized by low-temperature controlled rolling, but the fine grain steel technology provided by the invention can omit the low-temperature controlled rolling process, accelerate the rolling rhythm and realize the low-cost and high-efficiency production of hot rolled plate strip steel.

The invention adopts the following technical scheme:

the invention relates to a fine-grain hot-rolled plate strip steel, which comprises the following chemical components in percentage by mass: c: 0.03-0.35%, Si: 0.05-0.8%, Mn: 0.5-2.5%, P: 0.001-0.035%, S: 0.001-0.035%, Al: 0.001 to 0.07%, Ti: 0.002-0.05%, fine crystal elements: 0.0006 to 0.03%, O: 0.001-0.012%, N: 0.002-0.015% and the balance of Fe and inevitable impurities; wherein the fine crystal element is one or more of B, Mg, Zr and Ca;

the types of inclusions contained in the fine-grained hot rolled plate strip steel are as follows: al (Al)₂O₃Inclusions, TiO_xInclusions, TiN inclusions, AlN inclusions, MnS inclusions, inclusions formed of fine crystalline elements, and other unavoidable inclusions.

The fine-grained hot-rolled plate strip steel also comprises the following chemical components in percentage by mass: cr: 0.01-1%, Mo: 0.01-1%, Ni: 0.01-1%, Cu: 0.01-1%, Nb: 0.01-0.2%, V: 0.01-0.2% of one or more of the following components.

The microstructure type of the fine-grain hot-rolled plate strip steel is ferrite and/or bainite structure.

Wherein, the ferrite is one or more of polygonal shape, quasi-polygonal shape, granular shape or acicular shape, and the bainite is one or more of granular shape, acicular shape or lath shape; the longitudinal section of the fine-grain hot-rolled plate strip steel is a section with equal thickness or a section with variable thickness.

The yield strength of the fine-grained hot-rolled plate strip steel is 350-750 MPa, and the impact toughness at-20 ℃ is more than or equal to 47J.

More preferably: the fine-grained hot-rolled plate strip steel comprises the following chemical components in percentage by mass: c: 0.05-0.3%, Si: 0.1 to 0.7%, Mn: 0.8-1.8%, P: 0.002-0.03%, S: 0.002-0.03%, Al: 0.003 to 0.07%, Ti: 0.002-0.05%, B: 0.0006 to 0.003%, O: 0.001-0.01%, N: 0.003-0.015%, and the balance of Fe and inevitable impurities, and the formula is satisfied: 2[ O ] +3.43[ N ] - [ Ti ] -1.78 [ Al ] -4.38 [ B ] < 0.0172, wherein [ ] represents the mass fraction of the element in%.

The fine-grained hot-rolled plate strip steel contains Al₂O₃Inclusions, TiO_xInclusions, TiN inclusions, AlN inclusions, MnS inclusions, BN inclusionsAnd other inevitable inclusions;

the inclusions comprise composite inclusions and single-phase inclusions;

wherein, TiO is contained in all types of inclusions within the size range of 0.05-3 mu m according to the number of the particles of the inclusions_xThe number of composite inclusions of two or more of TiN, BN and MnS accounts for 10-80%;

wherein the composite inclusion is in accordance with TiO_xSequentially precipitating and separating out MnS, TiN and BN; and the average spacing of the composite inclusions is 5 to 100 μm.

Furthermore, according to the fine-grained hot-rolled plate strip steel, 20-80% of TiN exists in the form of single-phase inclusions in terms of the number of grains, and the rest TiN and other inclusions form composite inclusions; 30-90% of BN exists as single-phase inclusion, and the rest BN and other inclusions form composite inclusion; 40-90% of MnS exists as single-phase inclusion, and the rest MnS and other inclusions form composite inclusion.

Furthermore, the fine-grained hot-rolled plate strip steel further comprises the following fine-grained elements in percentage by mass, Zr: 0.001-0.025%, Mg: 0.001 to 0.01%, Ca: 0.001-0.01% of one or more of the following components; at the same time, ZrO is formed correspondingly in the fine-grained hot-rolled sheet-metal strip₂One or more oxides of MgO and CaO; the number of inclusions containing the above oxides and having a size of 0.1 to 5 μm is 100 to 3000 inclusions/mm²50 to 100% by number of the particles contain TiO in the inclusions_xOne or more precipitates of MnS, TiN and BN.

More preferably: the fine-grained hot-rolled plate strip steel comprises the following chemical components in percentage by mass: c: 0.03-0.25%, Si: 0.05-0.5%, Mn: 0.8-2.0%, P: 0.002-0.03%, S: 0.001 to 0.03%, Al: 0.003 to 0.07%, Ti: 0.002-0.05%, Mg: 0.001-0.01%, O: 0.001-0.01%, N: 0.003-0.015% and the balance of Fe and inevitable impurities.

The fine-grained hot-rolled plate strip steel contains Al₂O₃Inclusions, TiO_xInclusions, TiN inclusions, AlN inclusions, MnS inclusions, MgAl₂O₄Inclusions, and other unavoidable inclusions;

wherein the inclusions with a size of 0.03 to 3 μm contain MgAl₂O₄The number of the inclusions is 500 to 3000/mm²(ii) a 50-100% by number of particles of MgAl₂O₄Contains TiO on the surface of the inclusions_xInclusions or/and TiN inclusions as Mg-Ti composite inclusions; 50-100% of the Mg-Ti composite inclusions by number of particles contain MnS inclusions on the surface.

The fine-grained hot-rolled plate strip steel has two existing modes of TiN and MnS inclusions: exist alone and exist in a compound way with other inclusions; according to the amount of the particles, the TiN compounded with other inclusions accounts for 10-70% of all the TiN; MnS which is present in a composite manner with other inclusions accounts for 10-70% of the total MnS.

More preferably: the fine-grained hot-rolled plate strip steel comprises the following chemical components in percentage by mass: c: 0.03-0.25%, Si: 0.05-0.5%, Mn: 0.8-2.0%, P: 0.002-0.03%, S: 0.001-0.03%, Al: 0.003 to 0.07%, Ti: 0.002-0.05%, Zr: 0.001-0.03%, O: 0.001-0.012%, N: 0.002-0.012%, and the balance of Fe and inevitable impurities.

The fine-grained hot-rolled plate strip steel contains Al₂O₃Inclusions, TiO_xInclusions, TiN inclusions, AlN inclusions, MnS inclusions, ZrO inclusions₂Inclusions, ZrN inclusions and other unavoidable inclusions;

wherein the ZrO-containing glass fiber has a size of 0.03 to 3 μm₂The number density of the inclusions is 300 to 2000 pieces/mm²；

Containing ZrO₂In the inclusions (2), 50 to 100% by number of particles of ZrO₂Al on the surface of inclusions₂O₃、ZrN、TiO_xAt least one inclusion of TiN and MnS;

the fine-grained hot-rolled plate strip steel simultaneously contains ZrO₂The inclusions, MnS inclusions and titanium-containing inclusions account for all of the inclusions containing ZrO₂10-60% of the inclusions, wherein the titanium-containing inclusions comprise TiO_xInclusions and TiN inclusions.

The fine-grained hot-rolled sheet strip has an average grain size of 2 to 20 μm and contains at least 1 ZrO-containing grain per 3 grains on average₂、ZrN、TiO_xAnd one or more of TiN, AlN and MnS.

The invention relates to a preparation method of a fine-grain hot-rolled plate strip steel, which comprises the following steps:

step 1: smelting

Smelting molten iron and/or scrap steel materials into molten steel, tapping when the temperature of the molten steel reaches 1600-1700 ℃, the mass fraction of carbon in the molten steel is 0.02-0.15%, the mass fraction of phosphorus is 0.001-0.035%, and the mass fraction of sulfur is 0.001-0.045%, and adding a deoxidizer into a steel ladle for deoxidation in the tapping process; after tapping, the mass percentage content range of dissolved oxygen in the molten steel is 0.001-0.015%;

step 2: refining and continuous casting

Refining the tapped molten steel for 10-60 min; during or after refining, when the mass percentage of dissolved oxygen in the molten steel is 0.0002-0.01%, feeding a cored wire containing fine crystal elements and titanium into the molten steel to generate micron-sized or submicron-sized inclusions containing the fine crystal elements and the titanium, wherein the mass percentage of the dissolved oxygen in the molten steel is 0.0001-0.005%, and the mass percentage of total oxygen is 0.001-0.012%;

adding nitrogen-increasing alloy or bottom blowing nitrogen into molten steel, and controlling the mass percentage of total nitrogen in the molten steel as follows: 0.002-0.015%; adjusting the content of alloy elements in the molten steel according to the component requirements of the plate strip steel; carrying out full-protection casting on the molten steel to obtain a continuous casting slab;

and step 3: hot rolling

Heating the continuous casting plate blank to 1150-1250 ℃ for 30-300 min; removing scale by using high-pressure water after the steel plate is taken out of the furnace, and then continuously rolling the steel plate or the steel strip to obtain a hot-rolled steel plate or steel strip; wherein the rolling pass reduction rate is 8-35%; in the rolling process, inter-pass cooling temperature control is adopted, and the final rolling temperature is 900-1150 ℃;

and 4, step 4: cooling down

And cooling the hot rolled steel plate or steel strip to obtain the fine-grain hot rolled plate strip steel.

In the step 1, the deoxidizer is one or more of silicon, manganese, aluminum, calcium and barium or other common deoxidizers for steelmaking.

In the step 1, one of a converter and an electric furnace is adopted for smelting.

In the step 2, the refining is LF refining, and RH refining or VD refining can be performed after the LF refining.

In the step 2, when the fine crystal element is B, the core-spun yarn is a titanium-boron core-spun yarn, and is prepared by uniformly mixing and filling alloy powder containing titanium and boron and having the grain size of less than 3 mm; the alloy powder comprises the following chemical components in percentage by mass: ti: 20-60%, B: 1-20%, Si: 0.1-55%, Mn: 0.1 to 55%, O: 0.1-10%, Al: 0.1-10%, and the balance of iron and impurity elements; the titanium-boron core-spun yarn has the outer diameter of 10-16 mm and the yarn feeding speed of 100-300 m/min.

In the step 2, adding an alloy containing one or more elements of Zr, Mg and Ca at the same time of adding the titanium-boron cored wire or after adding the titanium-boron cored wire; wherein the total content of Zr, Mg and Ca elements accounts for 10-50% of the total mass of the alloy, and the balance is Si, Fe and inevitable impurities; after the alloy is added, ZrO with micron or submicron size can be correspondingly generated in molten steel₂One or more oxides of MgO and CaO, wherein in the molten steel, inclusions with a size of 0.1 to 5 μm are formed with the oxides as cores, and the number density of the inclusions is 100 to 3000/mm²。

In the step 2, when the fine crystal element is Mg, the core-spun yarn is a titanium-magnesium-nitrogen core-spun yarn which is prepared by uniformly mixing and filling alloy powder containing titanium, magnesium and nitrogen elements; wherein the grain diameter of the alloy powder containing titanium, magnesium and nitrogen elements is less than or equal to 3 mm; more specifically: the alloy powder comprises the following chemical components in percentage by mass: ti: 10-50%, Mg: 5-40%, N: 1-15%, Al: 0.1-10%, Si: 0.1-50%, Mn: 0.1-50%, and the balance of iron and impurity elements; the outer diameter of the titanium-magnesium-nitrogen core-spun yarn is 8-13 mm; the wire feeding speed of the titanium-magnesium-nitrogen core-spun wire is 80-200 m/min.

In the step 2, when the fine crystal element is Zr, the core-spun yarn is a titanium-zirconium-oxygen core-spun yarn, and the titanium-zirconium-oxygen core-spun yarn is prepared by uniformly mixing and filling alloy powder with the grain size of less than or equal to 3mm, wherein the alloy powder comprises the following chemical components in percentage by mass: ti: 20-50%, Zr: 10-40%, O: 1-10%, Al: 0.1-10%, Si: 0.1 to 50%, Mn: 0.1-50%, the balance being iron and unavoidable impurities; the outer diameter of the titanium zirconium oxygen core-spun yarn is 9-13 mm; the wire feeding speed of the titanium zirconium oxygen core-spun wire is 100-240 m/min.

In the step 2, the nitrogen-increasing alloy is one or a mixture of more of silicon nitride, manganese silicon nitride, chromium nitride and vanadium nitride.

In the step 3, the rolling process is completed on the same rolling mill or multiple rolling mills.

In the step 3, the heating is one of hot charging or furnace heating after off-line cooling.

In the step 3, in the rolling process, one or more times of cooling is carried out between rolling passes, and the cooling mode adopts one of water spray cooling, spray cooling or air cooling.

In the step 4, the cooling is one of natural cooling in air or on-line accelerated cooling, and when the on-line accelerated cooling is adopted, the start cooling temperature is 800-1100 ℃, the cooling speed is 10-200 ℃/s, and the final cooling temperature is 400-750 ℃.

The invention relates to a magnesium-containing fine-grain hot-rolled plate strip steel and a preparation method thereof, and the design concept of the technical scheme is as follows:

the chemical components and inclusions of the fine-grained hot-rolled plate strip steel are optimally designed, and cheap elements such as C-Si-Mn and the like are used as strengthening elements, so that the strength is ensured, and the cost is effectively controlled; aiming at the production process characteristics of the hot-rolled strip steel, the contents of inclusion forming elements such as Ti, B, Mg, Zr, Ca, Al, O, S and N are optimized, and expected inclusions are generated; particularly controls the type and the form of the inclusions in the steel, plays roles in pinning austenite grains and promoting intragranular ferrite phase transformation, and enables the ineffective inclusions in the conventional steel plate to play a beneficial effect so as to achieve the purpose of refining the grains.

According to the invention, a large number of researches show that when inclusions formed by the selected fine-grained elements are precipitated in a specific form through smelting process control according to different selected fine-grained elements, the method has an obvious double refining effect on the hot-rolled steel structure, can inhibit austenite grain coarsening under the high-temperature rolling rhythm, and can induce ferrite/bainite nucleation in the subsequent cooling process to further refine the structure, thereby playing a role in fine-grained strengthening. On the basis of no or little addition of noble metals such as Nb, V and the like, the reduction of production efficiency caused by complex processes is reduced, and the structure and the performance of steel are effectively ensured.

When the fine crystal element is B, in order to exert the structure refining effect of the inclusions to the maximum extent, the effective type, the optimal size, the spatial distribution and the number range of each inclusion are determined through a large number of experimental researches. And when Ti, Al, O, B, N satisfy the required content ranges and the relation 2[ O ] +3.43[ N ] - [ Ti ] -1.78 [ Al ] -4.38 [ B ] < 0.0172, formation of the target oxide and nitride is facilitated while reducing the adverse effects of ineffective inclusions or impurity elements.

In order to achieve the purpose, special control needs to be carried out on the production process of the steel, oxygen and nitrogen are usually removed as harmful impurity elements as much as possible in the conventional production process, while the content of oxygen and nitrogen is purposefully controlled in the production process, the generation of beneficial inclusions is not facilitated by too low oxygen and nitrogen content, and the properties of the steel are deteriorated due to too high oxygen and nitrogen content. In addition, the cored-wire containing fine crystalline elements needs to be fed into molten steel at a proper time to generate special inclusions with micron or submicron size, and the obtained inclusions are uniformly distributed, have reasonable number and size, and can be further combined with TiN or MnS to form the required composite inclusions. In the rolling stage, due to the double refining function of the composite inclusion, the conventional low-temperature controlled rolling process can be omitted, and under the condition of only carrying out high-temperature rolling, a fine-grain ferrite/bainite structure is obtained, so that the performance of the hot-rolled steel is improved.

The magnesium-containing fine-grain hot-rolled plate strip steel and the preparation method thereof have the advantages and beneficial effects that:

1. the invention fully utilizes the inclusion in the hot rolled steel, converts the harmful inclusion in the conventional steel into beneficial refined particles through component and process control, and leads the oxygen, the sulfur and the nitrogen which are considered as impurity elements under the normal condition to become beneficial elements which are beneficial to the improvement of the steel performance;

2. the invention enables the steel to have obvious structure refining capability by adopting the technical scheme of fine grain steel without changing the existing industrial equipment, thereby achieving the purpose of improving the obdurability of the steel, avoiding the addition of a large amount of precious alloy elements and reducing the production cost.

3. The scheme of the invention does not depend on low temperature to control rolling, simplifies the rolling process of hot rolled plate strip steel, reduces the industrial production difficulty, is beneficial to the control of production rhythm, shortens the production flow, reduces the resource and energy consumption and improves the production efficiency.

Drawings

FIG. 1 is an optical microstructure of a fine-grained hot rolled steel sheet prepared in example 1 of the present invention.

FIG. 2 is an optical microstructure of a fine-grained hot-rolled sheet strip produced in example 2 of the present invention.

FIG. 3 is an optical microstructure of a fine-grained hot-rolled steel sheet prepared in example 4 of the present invention.

FIG. 4 is an optical microstructure of a fine-grained hot-rolled steel sheet according to example 7 of the present invention.

FIG. 5 is an optical microstructure of a hot-rolled steel sheet strip in comparative example 1 of the present invention.

Detailed Description

The following examples are intended to illustrate specific embodiments of the present invention, but the scope of the present invention is not limited to the examples.

When the fine grain element is B, the preparation method of the fine grain hot rolled plate strip steel comprises the following steps:

step 1: smelting of

Smelting molten iron and/or scrap steel materials into molten steel by adopting a converter or an electric furnace, tapping when the temperature of the molten steel reaches 1600-1700 ℃, the mass fraction of carbon in the molten steel is 0.02-0.15%, the mass fraction of phosphorus is 0.001-0.035%, and the mass fraction of sulfur is 0.001-0.045%, and adding one or more of silicon, manganese, aluminum, calcium and barium or other common deoxidizing agents for steelmaking into a steel ladle in the tapping process to deoxidize; controlling the mass percentage content range of dissolved oxygen in the molten steel after tapping to be 0.001-0.015%;

step 2: refining and continuous casting

Refining the tapped molten steel into LF (ladle furnace) refining, wherein RH refining or VD refining can be carried out after the LF refining; removing impurities and adjusting temperature and adjusting components by deoxidation and desulfurization in the refining process, wherein each refining time is 10-60 min; during or after refining, when the mass percentage of dissolved oxygen in the molten steel is 0.0002-0.01%, feeding a titanium-boron core-spun yarn into the molten steel, and simultaneously blowing argon or nitrogen at the bottom of a steel ladle to generate micron-sized or submicron-sized titanium oxide, wherein the mass percentage of the dissolved oxygen in the molten steel is 0.0001-0.005%, and the mass percentage of the total oxygen is 0.001-0.012%; blowing nitrogen gas to the bottom of the molten steel or adding a nitrogen increasing alloy, wherein the nitrogen increasing alloy is one or a mixture of more of silicon nitride, manganese silicon nitride, chromium nitride and vanadium nitride, adjusting the mass fraction of nitrogen in the molten steel to 0.002-0.015%, and adjusting the content of each element in the molten steel according to the component requirement of the fine-grained hot rolled plate strip steel to obtain qualified molten steel;

the titanium-boron cored wire is prepared by uniformly mixing and filling alloy powder containing titanium and boron elements and having the grain size of less than 3 mm; the alloy powder comprises the following chemical components in percentage by mass: ti: 20-60%, B: 1-20%, Si: 0.1-55%, Mn: 0.1-55%, O: 0.1-10%, Al: 0.1-10%, and the balance of iron and impurity elements; the outer diameter of the titanium-boron core-spun yarn is 10-16 mm, and the yarn feeding speed is 100-300 m/min;

adding an alloy containing one or more elements of Zr, Mg and Ca at the same time or after the titanium boron core-spun yarn is added; wherein the total content of Zr, Mg and Ca elements accounts for 10-50% of the total mass of the alloy, and the balance is Si, Fe and inevitable impurities; after the alloy is added, ZrO with micron or submicron size can be correspondingly generated in molten steel₂One or more oxides of MgO and CaO, wherein in the molten steel, inclusions with a size of 0.1 to 5 μm are formed with the oxides as cores, and the number density of the inclusions is 100 to 3000/mm²；

Carrying out full-protection casting on the qualified molten steel through a continuous casting machine to obtain a continuous casting slab;

and step 3: hot rolling

Carrying out hot charging or cooling on the continuous casting plate blank, and then heating to 1150-1250 ℃ for 30-300 min; after discharging and descaling the plate blank, continuously rolling on the same rolling mill or a plurality of rolling mills, wherein the rolling pass reduction rate is 8-35%; in the rolling process, inter-pass cooling temperature control is adopted, and the final rolling temperature is 900-1150 ℃, so that a hot-rolled steel plate or a steel strip is obtained;

and 4, step 4: cooling down

Naturally cooling the hot rolled steel plate or steel strip in the air to room temperature to obtain fine-grain hot rolled plate strip steel; the cooling may also be an on-line accelerated cooling: and the start cooling temperature of the on-line accelerated cooling is 800-1100 ℃, the cooling speed is 10-200 ℃/s, the final cooling temperature is 400-750 ℃, the steel plate is air-cooled to room temperature after being straightened by a straightening machine, or the steel coil is air-cooled to room temperature after the steel strip is coiled, so that the fine-grained hot-rolled plate strip steel is obtained.

When the fine-grain element is Mg, the preparation method of the fine-grain hot-rolled plate strip steel comprises the following steps:

step 1: smelting

step 2: refining and continuous casting

Refining the tapped molten steel into LF (ladle furnace) refining, wherein RH refining or VD refining can be carried out after the LF refining; removing impurities and adjusting temperature and adjusting components by deoxidation and desulfurization in the refining process, wherein each refining time is 10-60 min; during or after refining, when the mass percentage of dissolved oxygen in the molten steel is 0.0002-0.01%, feeding a titanium magnesium nitrogen core-spun yarn into the molten steel, after feeding the titanium magnesium nitrogen core-spun yarn, blowing argon or nitrogen at the bottom of a steel ladle for 1-20 min to generate micron-sized or submicron-sized MgAl₂O₄Inclusions, TiO_xInclusions, wherein the mass percentage of dissolved oxygen in the molten steel is 0.0001-0.005%, and the mass percentage of total oxygen is 0.001-0.012%; adding a nitrogen-increasing alloy into the molten steel, wherein the nitrogen-increasing alloy is one or a mixture of more of silicon nitride, manganese silicon nitride, chromium nitride and vanadium nitride, adjusting the mass fraction of nitrogen in the molten steel to 0.002-0.015%, and adjusting the content of each element in the molten steel according to the component requirement of the fine-grain hot-rolled plate strip steel to obtain qualified molten steel; carrying out full-protection casting on the molten steel to obtain a continuous casting slab;

the titanium-magnesium-nitrogen cored wire is prepared by uniformly mixing and filling alloy powder containing titanium, magnesium and nitrogen elements; wherein the grain diameter of the alloy powder containing titanium, magnesium and nitrogen elements is less than or equal to 3 mm; more specifically: the alloy powder comprises the following chemical components in percentage by mass: ti: 10-50%, Mg: 5-40%, N: 1-15%, Al: 0.1-10%, Si: 0.1-50%, Mn: 0.1-50%, and the balance of iron and impurity elements; the outer diameter of the titanium-magnesium-nitrogen core-spun yarn is 8-13 mm; the wire feeding speed of the titanium-magnesium-nitrogen core-spun wire is 80-200 m/min;

and step 3: hot rolling

and 4, step 4: cooling down

When the fine grain element is Zr, the preparation method of the fine grain hot rolled plate strip steel comprises the following steps:

step 1: smelting

Smelting molten iron and/or steel scrap into molten steel by adopting a converter or an electric furnace, tapping when the temperature of the molten steel reaches 1600-1700 ℃, the mass fraction of carbon in the molten steel is 0.02-0.15%, the mass fraction of phosphorus is 0.001-0.035%, and the mass fraction of sulfur is 0.001-0.045%, and adding one or more of silicon, manganese, aluminum, calcium and barium or other common steelmaking deoxidizers into a steel ladle for deoxidation in the tapping process; controlling the mass percentage content range of dissolved oxygen in the molten steel after tapping to be 0.001-0.015%;

step 2: refining and continuous casting

Refining the tapped molten steel into LF (ladle furnace) refining, wherein RH refining or VD refining can be carried out after the LF refining; in the refining process, removing impurities and adjusting temperature and adjusting components by deoxidation and desulfurization, wherein each refining time is 10-60 min; feeding a titanium-zirconium-oxygen cored wire into the molten steel when the mass percentage of dissolved oxygen in the molten steel is 0.0002-0.01% in the refining process or after the refining process is finished, so as to generate zirconium oxide and titanium oxide with micron or submicron size, and enable the mass percentage of the dissolved oxygen in the molten steel to reach 0.0001-0.005% and the mass percentage of total oxygen to reach 0.001-0.012%; nitrogen is blown into the molten steel, a nitrogen increasing alloy is added, the nitrogen increasing alloy is one or a mixture of more of silicon nitride, manganese silicon nitride, chromium nitride and vanadium nitride, the mass fraction of nitrogen in the molten steel is adjusted to be 0.002-0.015%, and the content of each element in the molten steel is adjusted according to the component requirement of the fine-grain hot rolled plate strip steel, so that qualified molten steel is obtained; carrying out full-protection casting on the molten steel to obtain a continuous casting slab;

the titanium zirconium oxygen core-spun yarn is prepared by uniformly mixing and filling alloy powder with the grain diameter of less than or equal to 3mm, wherein the alloy powder comprises the following chemical components in percentage by mass: ti: 20-50%, Zr: 10-40%, O: 1-10%, Al: 0.1-10%, Si: 0.1-50%, Mn: 0.1-50%, the balance being iron and unavoidable impurities; the outer diameter of the titanium zirconium oxygen core-spun yarn is 9-13 mm; the wire feeding speed of the titanium zirconium oxygen core-spun wire is 100-240 m/min;

and step 3: hot rolling

and 4, step 4: cooling

Example 1

The embodiment is a preparation method of a fine-grain hot-rolled plate strip steel, which comprises the following steps:

step 1: smelting

Smelting molten iron and scrap steel materials (the mixing mass ratio is 1:1) into molten steel by adopting a converter, tapping when the temperature of the molten steel reaches 1650 ℃, the mass fraction of carbon in the molten steel is 0.05%, the mass fraction of phosphorus is 0.015%, and the mass fraction of sulfur is 0.035%, adding a mixture of silicon, manganese and aluminum (the mass ratio is 1:1:1) for deoxidation in the tapping process, and the mass fraction of dissolved oxygen in the molten steel is 0.005%;

step 2: refining and continuous casting

Performing LF refining on the tapped molten steel, and removing impurities and adjusting temperature and adjusting components by deoxidation and desulfurization in the refining process for 40 min; in the refining process, when the mass percentage of oxygen dissolved in the molten steel is 0.001%, feeding a titanium-boron core-spun yarn into the molten steel, wherein the titanium-boron core-spun yarn is prepared by uniformly mixing and filling alloy powder containing titanium and boron elements and having the particle size of less than 3mm, and the chemical components of the alloy powder comprise the following components in percentage by mass: ti: 50%, B: 10%, Si: 20%, Mn: 0.5%, O: 2%, Al: 6.5 percent, and the balance of iron and impurity elements; the outer diameter of the titanium-boron cored wire is 10mm, the wire feeding speed is 300m/min, meanwhile, argon is blown from the bottom of a steel ladle to generate titanium oxide with micron or submicron size, the mass percentage of dissolved oxygen in molten steel reaches 0.0005%, and the mass percentage of total oxygen reaches 0.006%; adding silicon nitride into the molten steel, adjusting the mass fraction of nitrogen in the molten steel to 0.004%, and adjusting the element content in the molten steel according to the component requirement of the fine-grain hot-rolled plate strip steel;

wherein, the component requirements of the fine-grained hot-rolled plate strip steel are as follows: comprises the following chemical components in percentage by mass: c: 0.25%, Si: 0.3%, Mn: 1.3%, P: 0.015%, S: 0.015%, Al: 0.016%, Ti: 0.02%, B: 0.0016%, O: 0.006%, N: 0.004%, and the balance of Fe and inevitable impurities, and satisfies the relation: 2[ O ] +3.43[ N ] - [ Ti ] -1.78 [ Al ] -4.38 [ B ] < 0.0172, wherein [ ] represents the mass fraction of the element in units;

and step 3: hot rolling

Heating the continuous casting plate blank to 1200 ℃ by a hot-conveying hot-charging device for 120 min; after the plate blank is taken out of the furnace and descaled, continuously rolling on a two-frame medium plate rolling mill, wherein the rolling pass reduction rate is 8-32%; in the rolling process, inter-pass cooling temperature control is adopted, and the final rolling temperature is 980 ℃ to obtain a hot-rolled steel plate;

and 4, step 4: cooling down

And naturally cooling the hot rolled steel plate to room temperature in the air to obtain the fine-grain hot rolled plate strip steel.

The prepared fine-grain hot-rolled plate strip steel contains Al₂O₃Inclusions, TiO_xInclusions, TiN inclusions, AlN inclusions, MnS inclusions, BN inclusions, and other unavoidable inclusions;

wherein, TiO is contained in all types of inclusions within the size range of 0.05-3 mu m according to the number of the particles of the inclusions_xThe amount of composite inclusions of two or more of TiN, BN and MnS is 75% by weight based on TiO_xThe precipitation of the order of → MnS → TiN → BN, and the average pitch of these composite inclusions was 32 μm.

The inclusions in the fine-grained hot-rolled plate strip steel are calculated according to the number of grains: 68% of TiN exists in single-phase inclusion, and the rest TiN and other inclusions form composite inclusions; 30 percent of BN exists as single-phase inclusion, and the balance of BN and other inclusions form composite inclusions; 75% of MnS is present as single-phase inclusions, and the balance MnS forms composite inclusions with other inclusions.

The microstructure picture of the prepared fine-grained hot-rolled plate strip steel is shown in figure 1, the microstructure picture of the fine-grained hot-rolled plate strip steel is analyzed to be a ferrite type structure, wherein ferrite is polygonal and acicular, the effective grain size is obviously refined, and the toughness is obviously improved; the longitudinal section of the steel plate is a variable thickness section.

The yield strength of the fine-grained hot-rolled plate strip steel is 420MPa, and the impact toughness at-20 ℃ is 210J.

Example 2

A preparation method of the fine-grain hot-rolled plate strip steel comprises the following steps:

step 1: smelting

Smelting the scrap steel into molten steel by adopting an electric furnace, tapping when the temperature of the molten steel reaches 1670 ℃, the mass fraction of carbon in the molten steel is 0.03%, the mass fraction of phosphorus is 0.01%, and the mass fraction of sulfur is 0.015%, adding a silicon-manganese mixture (the mass ratio is 1:1) in the tapping process for deoxidation, wherein the mass fraction of dissolved oxygen in the molten steel is 0.01%;

step 2: refining and continuous casting

Performing LF refining and RH refining on the tapped molten steel, removing impurities and adjusting temperature and adjusting components by deoxidation and desulfurization in the refining process, wherein the LF refining time is 35min, and the RH refining time is 30 min; after LF refining is finished, the mass percentage content of molten steel dissolved oxygen is 0.0005%, a titanium boron core-spun yarn is fed into the molten steel, the titanium boron core-spun yarn is prepared by uniformly mixing and filling alloy powder containing titanium and boron elements and having the grain size of less than 3mm, and the chemical components of the alloy powder comprise the following components in mass fraction: ti: 30%, B: 20%, Si: 1%, Mn: 25%, O: 8%, Al: 0.1 percent, and the balance of iron and impurity elements; the titanium boron core-spun yarn has the outer diameter of 12mm, the yarn feeding speed is 150m/min, nitrogen is blown to the bottom of a steel ladle at the same time to generate micron-sized or submicron-sized titanium oxide, the mass percentage of dissolved oxygen in molten steel reaches 0.0001%, and the mass percentage of total oxygen reaches 0.001%; adding manganese nitride into the molten steel, adjusting the mass fraction of nitrogen in the molten steel to 0.005%, and adjusting the element content in the molten steel according to the component requirement of the fine-grain hot-rolled plate strip steel;

wherein, the component requirements of the fine-grained hot-rolled plate strip steel are as follows: comprises the following chemical components in percentage by mass: c: 0.05%, Si: 0.2%, Mn: 1.5%, P: 0.01%, S: 0.005%, Al: 0.005%, Ti: 0.01%, B: 0.0025%, O: 0.001%, N: 0.005%, Cr: 0.1%, Mo: 0.1%, Ni: 0.2%, the balance being Fe and unavoidable impurities, and satisfying the relation: 2[ O ] +3.43[ N ] - [ Ti ] -1.78 [ Al ] -4.38 [ B ] < 0.0172, wherein [ ] represents the mass fraction of the element in units;

and step 3: hot rolling

Cooling the continuous casting plate blank, heating to 1220 ℃ for 150 min; after the plate blank is taken out of the furnace and descaled, continuously rolling on a hot continuous rolling mill, wherein the rolling pass reduction rate is 10-35%; in the rolling process, inter-pass cooling temperature control is adopted, and the final rolling temperature is 1020 ℃ to obtain a hot rolled steel strip;

and 4, step 4: cooling down

Carrying out on-line accelerated cooling on the hot rolled steel strip: and (3) accelerating the cooling starting temperature to 960 ℃, the cooling speed to 150 ℃/s and the final cooling temperature to 620 ℃, and cooling the steel coil to room temperature after the steel strip is coiled to obtain the fine-grain hot-rolled plate strip steel.

The prepared fine-grain hot-rolled plate strip steel contains Al₂O₃Inclusions, TiO_xInclusions, TiN inclusions, AlN inclusions, MnS inclusions, BN inclusions and other inevitable inclusions;

wherein, TiO is contained in all types of inclusions within the size range of 0.05-3 mu m according to the number of the particles of the inclusions_xThe amount of composite inclusions of two or more of TiN, BN and MnS is 21% by weight, based on TiO_xThe precipitation of the order of → MnS → TiN → BN, and the average pitch of these composite inclusions was 78 μm.

The inclusion in the fine-grained hot-rolled plate strip steel is calculated according to the number of particles: 35 percent of TiN exists in single-phase inclusion, and the balance of TiN and other inclusions form composite inclusions; 47 percent of BN exists as single-phase inclusions, and the balance of BN and other inclusions form composite inclusions; 55% of MnS is present as single-phase inclusions, and the balance MnS forms composite inclusions with other inclusions.

The microstructure diagram of the prepared fine-grained hot-rolled strip steel is shown in FIG. 2, and it can be seen from FIG. 2 that the optical microstructure of the prepared fine-grained hot-rolled strip steel is a ferrite and bainite structure, wherein the ferrite is in a quasi-polygonal shape and a needle shape, and the bainite is in a granular shape and a lath shape; the longitudinal section of the fine-grained hot-rolled plate strip steel is an equal-thickness section.

The yield strength of the fine-grained hot-rolled plate strip steel is 550MPa, and the impact toughness at the temperature of minus 20 ℃ is 230J.

Example 3

step 1: smelting

Smelting molten iron into molten steel by adopting a converter, tapping when the temperature of the molten steel reaches 1630 ℃, the mass fraction of carbon in the molten steel is 0.05%, the mass fraction of phosphorus is 0.013%, and the mass fraction of sulfur in the molten steel is 0.01%, and adding silicon, calcium and barium (1: 1:1) into a ladle for deoxidation in the tapping process; the mass percentage content of dissolved oxygen in the molten steel after tapping is 0.002%;

step 2: refining and continuous casting

Performing LF refining and VD refining on the tapped molten steel, removing impurities and adjusting temperature and adjusting components by deoxidation and desulfurization in the refining process, wherein the LF refining time is 20min, and the VD refining time is 60 min; in the VD refining process, the mass percentage of oxygen dissolved in the molten steel is 0.001%, a titanium-boron core-spun yarn is fed into the molten steel, the titanium-boron core-spun yarn is prepared by uniformly mixing and filling alloy powder containing titanium and boron elements and having the grain diameter of less than 3mm, and the chemical components of the alloy powder comprise the following components in percentage by mass: ti: 60%, B: 2%, Si: 20%, Mn: 2%, O: 0.5%, Al: 10 percent, and the balance of iron and impurity elements; the outer diameter of the titanium-boron core-spun yarn is 16mm, the yarn feeding speed is 100m/min, meanwhile, argon is blown from the bottom of a steel ladle to generate titanium oxide with micron or submicron size, the mass percentage of dissolved oxygen in molten steel reaches 0.0002%, and the mass percentage of total oxygen reaches 0.003%; after the titanium-boron cored wire is added, an alloy containing Ca element is added, wherein the content of the Ca element accounts for 30 percent of the total mass of the alloy, the balance is Si, iron and inevitable impurities, CaO with micron-sized or submicron-sized size is generated in molten steel, inclusions with the size of 0.1-5 mu m are formed by taking the CaO as a core, and the number density of the inclusions is 2500 inclusions/mm²(ii) a Adding vanadium nitride into the molten steel, and adjusting the mass fraction of nitrogen in the molten steel to 0.015%; adjusting the element content in the molten steel according to the component requirement of the fine-grain hot rolled plate strip steel;

wherein, the component requirements of the fine-grained hot-rolled plate strip steel are as follows: comprises the following chemical components in percentage by mass: c: 0.15%, Si: 0.1%, Mn: 1.8%, P: 0.01%, S: 0.003%, Al: 0.05%, Ti: 0.04%, B: 0.003%, Ca: 0.002%, O: 0.003%, N: 0.015%, Nb: 0.03%, V: 0.04%, and the balance of Fe and inevitable impurities, and satisfies the relation: 2[ O ] +3.43[ N ] - [ Ti ] -1.78 [ Al ] -4.38 [ B ] < 0.0172, wherein [ ] represents the mass fraction of the element in units;

and step 3: hot rolling

Heating the continuous casting plate blank to 1150 ℃ by a hot-conveying and hot-loading device for 50 min; after the plate blank is taken out of the furnace and descaled, continuously rolling on a medium plate rolling mill, wherein the rolling pass reduction rate is 8-35%; in the rolling process, inter-pass cooling temperature control is adopted, and the final rolling temperature is 900 ℃ to obtain a hot-rolled steel plate;

and 4, step 4: cooling down

Carrying out on-line accelerated cooling on the hot rolled steel plate: the start cooling temperature of the on-line accelerated cooling is 850 ℃, the cooling speed is 24 ℃/s, the final cooling temperature is 460 ℃, and the steel plate is straightened by a straightening machine and then air-cooled to the room temperature to obtain the fine-grain hot-rolled plate strip steel.

Al is contained in the prepared fine-grain hot-rolled plate strip steel₂O₃Inclusions, TiO_xInclusions, TiN inclusions, AlN inclusions, MnS inclusions, BN inclusions, CaO inclusions and other inevitable inclusions;

wherein, TiO is contained in all types of inclusions within the size range of 0.05-3 mu m according to the number of the particles of the inclusions_x56% of composite inclusions of two or more of TiN, BN and MnS in terms of TiO_xThe precipitation of the order of → MnS → TiN → BN, and the average pitch of these composite inclusions was 29 μm.

The inclusions in the fine-grained hot-rolled plate strip steel are calculated according to the number of grains: 40 percent of TiN exists in single-phase inclusion, and the balance of TiN and other inclusions form composite inclusions; 56 percent of BN exists as single-phase inclusion, and the balance of BN and other inclusions form composite inclusions; 85% of MnS is present as single-phase inclusions, and the balance MnS forms composite inclusions with other inclusions.

The number of inclusions containing CaO and having a size of 0.1 to 5 μm in the fine-grained hot-rolled sheet strip is 2500/mm²And the inclusions contain TiO in an amount of 70% by number of particles_xOne or more precipitates of TiN, BN and MnS.

The microstructure of the prepared fine-grain hot-rolled plate strip steel is ferrite and bainite, wherein the ferrite is acicular, and the bainite is lath-shaped and granular; the longitudinal section of the fine-grained hot-rolled plate strip steel is an equal-thickness section.

The yield strength of the fine-grained hot-rolled plate strip steel is 630MPa, and the impact toughness is 185J at the temperature of minus 20 ℃.

Example 4

step 1: smelting

Smelting molten iron and steel scrap (the molten iron and the steel scrap are 10:1 in mass ratio) into molten steel by adopting a converter, tapping when the temperature of the molten steel reaches 1700 ℃ and the mass fraction of carbon in the molten steel is 0.02%, the mass fraction of phosphorus is 0.001% and the mass fraction of sulfur is 0.001%, and adding silicon into a steel ladle for deoxidation in the tapping process; the mass percentage content of dissolved oxygen in the molten steel after tapping is 0.015 percent;

step 2: refining and continuous casting

Carrying out LF refining on the tapped molten steel, and removing impurities and adjusting temperature and adjusting components by deoxidation and desulfurization in the refining process, wherein the refining time is 15 min; in the refining process, when the mass percentage of oxygen dissolved in the molten steel is 0.01%, feeding a titanium-magnesium-nitrogen core-spun yarn into the molten steel, wherein the titanium-magnesium-nitrogen core-spun yarn is prepared by uniformly mixing and filling alloy powder containing titanium, magnesium and nitrogen elements and having the grain size of less than 3mm, and the chemical components of the alloy powder comprise the following components in percentage by mass: ti: 10%, Mg: 40%, N: 1.6%, Al: 0.1%, Si: 1%, Mn: 2 percent, and the balance of iron and impurity elements; the outer diameter of the titanium-magnesium-nitrogen cored wire is 8mm, the wire feeding speed is 200m/min, argon is blown to the bottom of a steel ladle for 20min after wire feeding, and MgAl with micron-sized or submicron-sized dimension is generated₂O₄Inclusions, TiO_xThe mass percent of the molten steel dissolved oxygen reaches 0.005%, and the mass percent of the total oxygen reaches 0.01%; adding silicon nitride and manganese into the molten steel, adjusting the mass fraction of nitrogen in the molten steel to 0.015 percent, and adjusting the element content in the molten steel according to the component requirement of the fine-grain hot-rolled plate strip steel; carrying out full-protection casting on the qualified molten steel through a continuous casting machine to obtain a continuous casting slab;

wherein, the component requirements of the fine-grained hot-rolled plate strip steel are as follows: comprises the following chemical components in percentage by mass: c: 0.03%, Si: 0.4%, Mn: 0.8%, P: 0.002%, S: 0.002%, Al: 0.003%, Ti: 0.002%, Mg: 0.008%, O: 0.01%, N: 0.015% and the balance of Fe and inevitable impurities;

and step 3: hot rolling

Heating the continuous casting plate blank to 1210 ℃ by a hot-conveying hot-charging device for 100 min; after the plate blank is taken out of the furnace and descaled, continuously rolling on a two-frame medium plate rolling mill, wherein the rolling pass reduction rate is 8-32%; in the rolling process, inter-pass cooling temperature control is adopted, and the final rolling temperature is 1000 ℃, so that a hot-rolled steel plate is obtained;

and 4, step 4: cooling down

The hot-rolled fine-grained plate strip prepared in this example contained Al₂O₃Inclusion, TiO_xInclusions, TiN inclusions, AlN inclusions, MnS inclusions, MgAl₂O₄Inclusions, and other unavoidable inclusions;

wherein the inclusions with a size of 0.03 to 3 μm contain MgAl₂O₄The number of inclusions of (2) is 2800 pieces/mm²(ii) a 60% by number of particles of MgAl₂O₄Contains TiO on the surface of the inclusions_xInclusions or/and TiN inclusions as Mg-Ti composite inclusions; on the basis of the number of particles, 75% of the Mg-Ti composite inclusions contained MnS inclusions on the surface.

The prepared fine-grained hot-rolled strip steel has two existing modes of TiN and MnS inclusions: exist alone and exist in a compound way with other inclusions; the TiN which is combined with other inclusions accounts for 20 percent of the total TiN according to the quantity of the particles; MnS present in combination with other inclusions accounts for 30% of the total MnS.

The average grain size of the fine-grained hot-rolled sheet strip prepared in this example was 7 μm, and the microstructure thereof is shown in fig. 3, from which fig. 3 it can be seen that the microstructure thereof is polygonal ferrite and quasi-polygonal ferrite; the shape of the longitudinal section of the fine-grained hot-rolled plate strip steel is a variable-thickness section.

The yield strength of the fine-grained hot-rolled plate strip steel prepared by the embodiment is 370MPa, and the impact toughness at-20 ℃ is 280J.

Example 5

A preparation method of a fine-grain hot-rolled plate strip steel comprises the following steps:

step 1: smelting

Smelting molten iron into molten steel by adopting a converter, tapping when the temperature of the molten steel reaches 1600 ℃, and the mass fraction of carbon in the molten steel is 0.15%, the mass fraction of phosphorus is 0.035%, and the mass fraction of sulfur is 0.045%, and adding manganese into a steel ladle for deoxidation in the tapping process; the mass percentage content of dissolved oxygen in the molten steel after tapping is 0.01 percent;

step 2: refining and continuous casting

Performing LF refining and RH refining on the tapped molten steel, removing impurities and adjusting temperature and adjusting components by deoxidation and desulfurization in the refining process, wherein the LF refining time is 10min, and the RH refining time is 60 min; in the LF refining process, when the mass percentage of dissolved oxygen in the molten steel is 0.001%, feeding a titanium-magnesium-nitrogen core-spun yarn into the molten steel, wherein the titanium-magnesium-nitrogen core-spun yarn is prepared by uniformly mixing and filling alloy powder containing titanium, magnesium and nitrogen elements and having the grain size of less than 3mm, and the chemical components of the alloy powder comprise the following components in percentage by mass: ti: 50%, Mg: 5%, N: 15%, Al: 10%, Si: 10%, Mn: 0.1 percent, and the balance of iron and impurity elements; the outer diameter of the titanium-magnesium-nitrogen cored wire is 13mm, the wire feeding speed is 80m/min, nitrogen is blown to the bottom of a steel ladle for 1min after the wire feeding, and MgAl with micron-grade or submicron-grade size is generated₂O₄Inclusions, TiO_xThe mass percentage of molten steel dissolved oxygen reaches 0.0001 percent, and the mass percentage of total oxygen reaches 0.002 percent; adding chromium nitride into the molten steel, adjusting the mass fraction of nitrogen in the molten steel to 0.003 percent, and adjusting the element content in the molten steel according to the component requirement of the fine-grain hot-rolled plate strip steel; carrying out full-protection casting on the qualified molten steel through a continuous casting machine to obtain a continuous casting slab;

wherein, the component requirements of the fine-grained hot-rolled plate strip steel are as follows: comprises the following chemical components in percentage by mass: c: 0.25%, Si: 0.5%, Mn: 1.0%, P: 0.03%, S: 0.03%, Al: 0.03%, Ti: 0.05%, Mg: 0.001%, O: 0.002%, N: 0.003%, Cr: 0.1%, Mo: 0.2%, the balance being Fe and unavoidable impurities;

and step 3: hot rolling

Cooling the continuous casting plate blank, then heating to 1250 ℃, and heating for 300 min; after discharging and descaling the plate blank, continuously rolling on a hot continuous rolling mill, wherein the rolling pass reduction rate is 8-35%; in the rolling process, inter-pass cooling temperature control is adopted, and the final rolling temperature is 1150 ℃, so that a hot rolled steel strip is obtained;

and 4, step 4: cooling down

Carrying out on-line accelerated cooling on the hot rolled steel strip: and (3) accelerating the cooling starting temperature to be 1100 ℃, the cooling speed to be 200 ℃/s and the final cooling temperature to be 750 ℃, and cooling the steel coil to room temperature after the steel strip is coiled to obtain the fine-grain hot-rolled plate strip steel.

wherein the inclusions with a size of 0.03 to 3 μm contain MgAl₂O₄The number of inclusions in (2) is 550 pieces/mm²(ii) a Contains MgAl in an amount of 80% by number of the particles₂O₄Contains TiO on the surface of the inclusions_xInclusions or/and TiN inclusions as Mg-Ti composite inclusions; on the basis of the number of particles, 90% of the Mg-Ti composite inclusions contained MnS inclusions on the surface.

The TiN and MnS inclusion contained in the prepared fine-grained hot-rolled plate strip steel has two existing modes: exist alone and exist in a compound way with other inclusions; according to the amount of the particles, TiN compounded with other inclusions accounts for 60 percent of the total TiN; MnS present in combination with other inclusions accounts for 40% of the total MnS.

The average grain size of the fine-grain hot-rolled plate strip steel prepared by the embodiment is 15 mu m, and the microstructure is a quasi-polygonal ferrite and granular bainite structure; the longitudinal section of the fine-grained hot-rolled plate strip steel is an equal-thickness section.

The yield strength of the fine-grained hot-rolled plate strip steel prepared by the embodiment is 450MPa, and the impact toughness at-20 ℃ is 150J.

Example 6

step 1: smelting:

smelting the scrap steel into molten steel by adopting an electric furnace, tapping when the temperature of the molten steel reaches 1670 ℃, the mass fraction of carbon in the molten steel is 0.05%, the mass fraction of phosphorus is 0.01%, and the mass fraction of sulfur is 0.02%, and adding aluminum to the ladle for deoxidation in the tapping process; the mass percentage content of dissolved oxygen in the molten steel after tapping is 0.01 percent;

step 2: refining and continuous casting

Performing LF refining and RH refining on the tapped molten steel, removing impurities and adjusting temperature and adjusting components by deoxidation and desulfurization in the refining process, wherein the LF refining time is 60min, and the RH refining time is 50 min; in the RH refining process, when the mass percentage of oxygen dissolved in the molten steel is 0.009%, feeding a titanium-magnesium-nitrogen core-spun yarn into the molten steel, wherein the titanium-magnesium-nitrogen core-spun yarn is prepared by uniformly mixing and filling alloy powder containing titanium, magnesium and nitrogen elements and having the grain diameter of less than 3mm, and the chemical components of the alloy powder comprise the following components in percentage by mass: ti: 20%, Mg: 25%, N: 3%, Al: 2%, Si: 3%, Mn: 20 percent of iron and impurity elements in balance; the outer diameter of the titanium-magnesium-nitrogen cored wire is 10mm, the wire feeding speed is 120m/min, argon and nitrogen are blown to the bottom of a steel ladle for 10min and 10min after wire feeding, and MgAl with micron or submicron size is generated₂O₄Inclusion, TiO_xInclusions, wherein the mass percent of molten steel dissolved oxygen reaches 0.001%, and the mass percent of total oxygen reaches 0.007%; adding vanadium nitride into the molten steel, adjusting the mass fraction of nitrogen in the molten steel to 0.003 percent, and adjusting the element content in the molten steel according to the component requirement of the fine-grain hot-rolled plate strip steel; carrying out full-protection casting on the qualified molten steel through a continuous casting machine to obtain a continuous casting slab;

wherein, the component requirements of the fine-grained hot-rolled plate strip steel are as follows: comprises the following chemical components in percentage by mass: c: 0.15%, Si: 0.25%, Mn: 1.5%, P: 0.01%, S: 0.02%, Al: 0.03%, Ti: 0.03%, Mg: 0.007%, O: 0.007%, N: 0.003%, V: 0.01%, the balance being Fe and unavoidable impurities;

and step 3: hot rolling

Heating the continuous casting plate blank to 1200 ℃ in a hot conveying and hot loading manner for 40 min; after the plate blank is taken out of the furnace and descaled, continuously rolling on a medium plate rolling mill, wherein the rolling pass reduction rate is 8-35%; in the rolling process, inter-pass cooling temperature control is adopted, and the final rolling temperature is 920 ℃, so that a hot-rolled steel plate is obtained;

and 4, step 4: cooling down

Carrying out on-line accelerated cooling on the hot rolled steel plate: and the opening cooling temperature of the online accelerated cooling is 880 ℃, the cooling speed is 50 ℃/s, the final cooling temperature is 500 ℃, and the steel plate is straightened by a straightening machine and then air-cooled to the room temperature to obtain the fine-grain hot-rolled plate strip steel.

The hot-rolled fine-grained plate strip prepared in this example contained Al₂O₃Inclusions, TiO_xInclusions, TiN inclusions, AlN inclusions, MnS inclusions, MgAl₂O₄Inclusions, and other unavoidable inclusions;

wherein the inclusions with a size of 0.03 to 3 μm contain MgAl₂O₄The number of inclusions in (A) is 2400/mm²(ii) a 60% by number of particles of MgAl₂O₄Contains TiO on the surface of the inclusions_xInclusions or/and TiN inclusions as Mg-Ti composite inclusions; 100% by number of particles of the Mg-Ti composite inclusion contained MnS inclusions on the surface.

The prepared fine-grained hot-rolled strip steel has two existing modes of TiN and MnS inclusions: exists alone and in combination with other inclusions; the TiN which is combined with other inclusions accounts for 10 percent of the total TiN according to the amount of the particles; MnS present in combination with other inclusions accounts for 70% of the total MnS.

The average grain size of the fine-grained hot-rolled plate strip steel prepared by the embodiment is 3 mu m, and the microstructure is granular bainite and lath bainite; the longitudinal section of the fine-grained hot-rolled plate strip steel is an equal-thickness section.

The yield strength of the fine-grained hot-rolled plate strip steel prepared by the embodiment is 440MPa, and the impact toughness at-20 ℃ is 280J.

Example 7

A preparation method of a fine-grain hot-rolled plate strip steel comprises the following process steps:

step 1: smelting of

Smelting molten iron and steel scrap (the molten iron and the steel scrap are 2:1 in mass ratio) into molten steel by adopting a converter, tapping when the temperature of the molten steel reaches 1660 ℃ and the mass fraction of carbon in the molten steel is 0.05%, the mass fraction of phosphorus is 0.01% and the mass fraction of sulfur is 0.02%, and adding silicon into a ladle for deoxidation in the tapping process; the mass percentage content of dissolved oxygen in the molten steel after tapping is 0.01 percent;

step 2: refining and continuous casting

Carrying out LF refining on the tapped molten steel, and removing impurities and adjusting temperature and adjusting components by deoxidation and desulfurization in the refining process, wherein the refining time is 35 min; in the refining process, when the mass percentage of oxygen dissolved in the molten steel is 0.009%, feeding a titanium-zirconium-oxygen cored wire into the molten steel, wherein the titanium-zirconium-oxygen cored wire is prepared by uniformly mixing and filling alloy powder with the particle size of less than or equal to 3mm, and the alloy powder comprises the following chemical components in percentage by mass: ti: 20%, Zr: 40%, O: 10%, Al: 10%, Si: 0.1%, Mn: 0.1%, the balance being iron and unavoidable impurities; the outer diameter of the titanium zirconium oxygen core-spun yarn is 9mm, the yarn feeding speed is 100m/min, argon is blown to the bottom of a steel ladle for 20min to generate zirconium oxide and titanium oxide with micron or submicron size, the mass percentage of the molten steel dissolved oxygen reaches 0.005%, and the mass percentage of the total oxygen reaches 0.01%; blowing nitrogen into the molten steel, adjusting the mass fraction of nitrogen in the molten steel to 0.002%, and adjusting the content of elements in the molten steel according to the component requirement of the fine-grained hot-rolled plate strip steel to obtain qualified molten steel; carrying out full-protection casting on the molten steel to obtain a continuous casting slab;

wherein, the component requirements of the fine-grained hot-rolled plate strip steel are as follows: comprises the following chemical components in percentage by mass: c: 0.1%, Si: 0.4%, Mn: 1.8%, P: 0.012%, S: 0.012%, Al: 0.03%, Ti: 0.003%, Zr: 0.01%, O: 0.01%, N: 0.002%, and the balance of Fe and inevitable impurities;

and step 3: hot rolling

Heating the continuous casting plate blank to 1220 ℃ by a hot-conveying hot-charging device for 90 min; after the plate blank is taken out of the furnace and descaled, continuously rolling on a two-frame medium plate rolling mill, wherein the rolling pass reduction rate is 8-32%; in the rolling process, inter-pass cooling temperature control is adopted, and the final rolling temperature is 1100 ℃, so that a hot-rolled steel plate is obtained;

and 4, step 4: cooling

The hot rolled steel sheet was naturally cooled to room temperature in the air to obtain a fine-grained hot rolled sheet strip, and the optical microstructure thereof was analyzed to obtain an optical microstructure chart shown in FIG. 4.

The fine-grained hot-rolled plate strip prepared in this example contains Al₂O₃Inclusions, TiO_xInclusions, TiN inclusions, AlN inclusions, MnS inclusions, ZrO inclusions₂Inclusions, ZrN inclusions and other unavoidable inclusions; ZrO contained in steel with size of 0.03-3 μm₂The number of inclusions in (A) is 1600/mm²(ii) a In the presence of ZrO₂In which 75% by number of particles of the inclusions contain Al on the surface₂O₃、ZrN、TiO_xAt least one inclusion of TiN and MnS; the steel containing ZrO at the same time₂And MnS and TiO_xOr/and TiN in an amount of all ZrO-containing inclusions₂40% of the number of inclusions.

In the embodiment, the microstructure of the prepared fine-grain hot-rolled plate strip steel is polygonal ferrite; the longitudinal section of the fine-grained hot-rolled plate strip steel is an equal-thickness section.

A fine-grained hot-rolled steel sheet having an average grain size of 12 μm and containing at least 1 ZrO contained in an average of 3 grains₂、ZrN、TiO_xAnd one or more of TiN, AlN, and MnS.

The yield strength of the fine-grained hot-rolled plate strip steel prepared by the embodiment is 350MPa, and the impact toughness at-20 ℃ is 150J.

Example 8

step 1: smelting

Smelting molten iron and scrap steel (the molten iron and the scrap steel are 1:2 in mass ratio) into molten steel by using an electric furnace, tapping when the temperature of the molten steel reaches 1680 ℃ and the mass fraction of carbon in the molten steel is 0.06%, the mass fraction of phosphorus is 0.015% and the mass fraction of sulfur is 0.025%, and adding silicon and calcium (in mass ratio of 1:1) into a steel ladle to deoxidize in the tapping process; the mass percentage content of dissolved oxygen in the molten steel after tapping is 0.002%;

step 2: refining and continuous casting

Performing LF refining and RH refining on the tapped molten steel, removing impurities and adjusting temperature and adjusting components by deoxidation and desulfurization in the refining process, wherein the LF refining time is 40min, and the RH refining time is 60 min; in the LF refining process, when the mass percentage of oxygen dissolved in molten steel is 0.001%, feeding a titanium-zirconium-oxygen cored wire into the molten steel, wherein the titanium-zirconium-oxygen cored wire is prepared by uniformly mixing and filling alloy powder with the particle size of less than or equal to 3mm, and the alloy powder comprises the following chemical components in percentage by mass: ti: 50%, Zr: 15%, O: 1%, Al: 3%, Si: 4%, Mn: 15%, the balance being iron and unavoidable impurities; the outer diameter of the titanium-zirconium-oxygen cored wire is 11mm, the wire feeding speed is 150m/min, zirconium oxide and titanium oxide with micron-sized or submicron-sized dimensions are generated, the mass percentage of dissolved oxygen in molten steel reaches 0.001%, and the mass percentage of total oxygen reaches 0.003%; adding chromium nitride into the molten steel, adjusting the mass fraction of nitrogen in the molten steel to 0.01%, and adjusting the element content in the molten steel according to the component requirement of the fine-grain hot-rolled plate strip steel to obtain qualified molten steel; carrying out full-protection casting on the molten steel to obtain a continuous casting slab;

wherein, the component requirements of the fine-grained hot-rolled plate strip steel are as follows: comprises the following chemical components in percentage by mass: c: 0.12%, Si: 0.3%, Mn: 1.3%, P: 0.015%, S: 0.008%, Al: 0.03%, Ti: 0.03%, Zr: 0.002%, O: 0.003%, N: 0.01%, Cr: 1%, and the balance of Fe and inevitable impurities;

and step 3: hot rolling

Cooling the continuous casting plate blank, then heating to 1160 ℃ for 200 min; after the plate blank is taken out of the furnace and descaled, continuously rolling on a hot continuous rolling mill, wherein the rolling pass reduction rate is 10-35%; in the rolling process, inter-pass cooling temperature control is adopted, and the final rolling temperature is 990 ℃, so that a hot rolled steel strip is obtained;

and 4, step 4: cooling

Carrying out on-line accelerated cooling on the hot rolled steel strip: the cooling starting temperature is 950 ℃, the cooling speed is 80 ℃/s, the final cooling temperature is 450 ℃, and the steel coil is air-cooled to the room temperature after the steel strip is coiled, so that the fine-grain hot-rolled plate strip steel is obtained.

The fine-grained hot-rolled plate strip prepared in this example contains Al₂O₃Inclusions, TiO_xInclusions, TiN inclusions, AlN inclusions, MnS inclusions, ZrO inclusions₂Inclusions, ZrN inclusions, and other unavoidable inclusions; ZrO contained in steel with a size of 0.03 to 3 μm₂The number of inclusions of (2) is 400 pieces/mm²(ii) a In the presence of ZrO₂In the inclusions (2), 100% of the surface of the inclusions contains Al in terms of the number of particles₂O₃、ZrN、TiO_xAt least one inclusion of TiN and MnS; the steel containing ZrO at the same time₂And MnS and TiO_xOr/and TiN in an amount of all ZrO-containing inclusions₂The number of inclusions is 60%.

In the embodiment, the microstructure of the prepared fine-grain hot-rolled plate strip steel is acicular ferrite and granular bainite; the longitudinal section of the fine-grained hot-rolled plate strip steel is an equal-thickness section.

A fine-grained hot-rolled steel sheet having an average grain size of 4 μm and containing at least 1 ZrO-containing grain per 3 grains on average₂、ZrN、TiO_xAnd one or more of TiN, AlN and MnS.

The yield strength of the fine-grained hot-rolled plate strip steel prepared by the embodiment is 750MPa, and the impact toughness at-20 ℃ is 165J.

Example 9

step 1: smelting

Smelting molten iron and scrap steel (the molten iron and the scrap steel are 1:3 in mass ratio) into molten steel by using an electric furnace, tapping when the temperature of the molten steel reaches 1690 ℃ and the mass fraction of carbon in the molten steel is 0.08%, the mass fraction of phosphorus is 0.02% and the mass fraction of sulfur is 0.02%, and adding aluminum into a steel ladle for deoxidation in the tapping process; the mass percentage content of dissolved oxygen in the molten steel after tapping is 0.01 percent;

step 2: refining and continuous casting

Carrying out LF refining and VD refining on the tapped molten steel, removing impurities and adjusting temperature and adjusting components by deoxidation and desulfurization in the refining process, wherein the LF refining time is 30min, and the VD refining time is 30 min; after VD refining is finished, when the mass percentage of oxygen dissolved in the molten steel is 0.0006%, feeding a titanium-zirconium-oxygen cored wire into the molten steel, wherein the titanium-zirconium-oxygen cored wire is prepared by uniformly mixing and filling alloy powder with the particle size of less than or equal to 3mm, and the alloy powder comprises the following chemical components in percentage by mass: ti: 30%, Zr: 30%, O: 8%, Al: 6%, Si: 0.1%, Mn: 10%, the balance being iron and unavoidable impurities; the outer diameter of the titanium-zirconium-oxygen cored wire is 13mm, the wire feeding speed is 240m/min, zirconium oxide and titanium oxide with micron-sized or submicron-sized dimensions are generated, the mass percentage of dissolved oxygen in molten steel reaches 0.0005%, and the mass percentage of total oxygen reaches 0.001%; adding manganese nitride into the molten steel, adjusting the mass fraction of nitrogen in the molten steel to reach 0.003%, and adjusting the content of elements in the molten steel according to the component requirement of the fine-grained hot rolled plate strip steel to obtain qualified molten steel; carrying out full-protection casting on the molten steel to obtain a continuous casting slab;

wherein, the component requirements of the fine-grained hot-rolled plate strip steel are as follows: comprises the following chemical components in percentage by mass: c: 0.22%, Si: 0.05%, Mn: 1.1%, P: 0.012%, S: 0.005%, Al: 0.07%, Ti: 0.04%, Zr: 0.03%, O: 0.001%, N: 0.003%, Ni: 0.5%, Cu: 0.5%, the balance being Fe and unavoidable impurities;

and step 3: hot rolling

Heating the continuous casting plate blank to 1250 ℃ in a hot conveying and hot loading mode for 90 min; after the plate blank is taken out of the furnace and descaled, continuously rolling on a medium plate rolling mill, wherein the rolling pass reduction rate is 8-35%; in the rolling process, inter-pass cooling temperature control is adopted, and the final rolling temperature is 1150 ℃, so that a hot-rolled steel plate is obtained;

and 4, step 4: cooling down

Carrying out on-line accelerated cooling on the hot rolled steel plate: the start cooling temperature of the on-line accelerated cooling is 1100 ℃, the cooling speed is 15 ℃/s, the final cooling temperature is 430 ℃, and the steel plate is straightened by a straightening machine and then air-cooled to the room temperature to obtain the fine-grain hot-rolled plate strip steel.

The fine-grained hot-rolled plate strip prepared in this example contains Al₂O₃Inclusions, TiO_xInclusions, TiN inclusions, AlN inclusions, MnS inclusions, ZrO inclusions₂Inclusions, ZrN inclusions and other unavoidable inclusions; ZrO contained in steel with a size of 0.03 to 3 μm₂The number of inclusions of (2) is 1960 pieces/mm²(ii) a In the presence of ZrO₂In which 55% by number of particles of the inclusions contain Al on the surface₂O₃、ZrN、TiO_xAt least one inclusion of TiN and MnS; the steel containing ZrO at the same time₂And MnS and TiO_xOr/and TiN in an amount of all ZrO-containing inclusions₂12% of the number of inclusions.

In the embodiment, the microstructure of the prepared fine-grain hot-rolled strip steel is needle-shaped, granular and lath-shaped bainite; the shape of the longitudinal section of the fine-grain hot-rolled plate strip steel is a variable-thickness section;

a fine-grained hot-rolled steel sheet having an average grain size of 5 μm and containing at least 1 ZrO-containing grain per 3 grains on average₂、ZrN、TiO_xAnd one or more of TiN, AlN and MnS.

The yield strength of the fine-grained hot-rolled plate strip steel prepared by the embodiment is 700MPa, and the impact toughness at-20 ℃ is 145J.

Comparative example 1

A preparation method of hot-rolled plate strip steel comprises the following steps:

step 1: smelting

Smelting molten iron and scrap steel (the mixing mass ratio is 1:1) into molten steel by adopting a converter, tapping when the temperature of the molten steel reaches 1660 ℃, the mass fraction of carbon in the molten steel is 0.07%, the mass fraction of phosphorus is 0.012%, and the mass fraction of sulfur is 0.03%, adding a silicon-manganese mixture (the mass ratio is 1:1) in the tapping process for deoxidation, wherein the mass fraction of dissolved oxygen in the molten steel is 0.01%;

step 2: refining and continuous casting

Carrying out LF refining on the tapped molten steel, and carrying out deoxidation and desulfurization to remove impurities and adjust temperature and adjust components in the refining process for 30 min; feeding a titanium wire in the refining process, wherein the outer diameter of the titanium wire is 13mm, and the mass fraction of the titanium element is 40%; carrying out full-protection casting through a continuous casting machine after refining the molten steel to obtain a continuous casting slab;

the hot-rolled plate strip steel comprises the following chemical components in percentage by mass: c: 0.1%, Si: 0.4%, Mn: 1.1%, P: 0.012%, S: 0.005%, Al: 0.02%, Ti: 0.02%, O: 0.005%, N: 0.003%, the balance being Fe and inevitable impurities;

and step 3: hot rolling

Heating the continuous casting plate blank to 1200 ℃ by a hot-conveying hot-charging device for 100 min; after the plate blank is taken out of the furnace and descaled, continuously rolling on a two-frame medium plate rolling mill, wherein the rolling pass reduction rate is 8-32%; in the rolling process, inter-pass cooling temperature control is adopted, and the final rolling temperature is 1000 ℃, so that a hot-rolled steel plate is obtained;

and 4, step 4: cooling down

Carrying out on-line accelerated cooling on the hot rolled steel plate: the start cooling temperature of the on-line accelerated cooling is 900 ℃, the cooling speed is 40 ℃/s, the final cooling temperature is 600 ℃, and the steel plate is straightened by a straightener and then air-cooled to the room temperature to obtain the hot-rolled plate strip steel.

The microstructure of the prepared hot-rolled strip steel is shown in figure 5, and figure 5 shows that the microstructure of the prepared hot-rolled strip steel is widmannstatten structure and granular ferrite, and the grain size is coarsened, so that the mechanical property is reduced.

The yield strength of the prepared hot rolled strip steel is 330MPa, and the impact toughness at-20 ℃ is 25J.

Because only the conventional titanium wire is fed in the comparative example, a fine-grain microstructure can not be obtained under the high-temperature hot rolling condition, and the toughness can not be effectively improved.

Comparative example 2

step 1: smelting

Smelting the scrap steel into molten steel by adopting an electric furnace, tapping when the temperature of the molten steel reaches 1670 ℃, the mass fraction of carbon in the molten steel is 0.1%, the mass fraction of phosphorus is 0.015%, and the mass fraction of sulfur is 0.015%, and adding Al for deoxidation in the tapping process, wherein the mass fraction of dissolved oxygen in the molten steel is 0.0008%;

step 2: refining and continuous casting

Performing LF refining and RH refining on the tapped molten steel, removing impurities and adjusting temperature and adjusting components by deoxidation and desulfurization in the refining process, wherein the LF refining time is 40min, and the RH refining time is 40 min; after LF refining is finished, the mass percentage content of molten steel dissolved oxygen is 0.00015%, a titanium boron core-spun yarn is fed into the molten steel, the titanium boron core-spun yarn is prepared by uniformly mixing and filling alloy powder containing titanium and boron elements and having the grain size of less than 3mm, and the chemical components of the alloy powder comprise the following components in mass fraction: ti: 40%, B: 30 percent of iron and impurity elements; the titanium-boron cored wire has the outer diameter of 12mm, the wire feeding speed of 150m/min, and simultaneously argon gas is blown from the bottom of a ladle, the mass percentage of the molten steel dissolved oxygen is 0.00009%, and the mass percentage of the total oxygen is 0.0005%; adding manganese nitride into the molten steel, and adjusting the mass fraction of nitrogen in the molten steel to 0.006%; carrying out full-protection casting on the refined molten steel through a continuous casting machine to obtain a continuous casting slab;

the hot-rolled plate strip steel comprises the following chemical components in percentage by mass: c: 0.15%, Si: 0.25%, Mn: 1.5%, P: 0.011%, S: 0.015%, Al: 0.05%, Ti: 0.03%, B: 0.004%, O: 0.0005%, N: 0.006%, Cr: 0.1%, Mo: 0.1%, Ni: 0.2%, the balance being Fe and unavoidable impurities;

and step 3: hot rolling

Cooling the continuous casting plate blank, heating to 1180 ℃ for 150 min; after the plate blank is taken out of the furnace and descaled, continuously rolling on a hot continuous rolling mill, wherein the rolling pass reduction rate is 10-35%; in the rolling process, inter-pass cooling temperature control is adopted, and the final rolling temperature is 1010 ℃, so that a hot rolled steel strip is obtained;

and 4, step 4: cooling down

Carrying out on-line accelerated cooling on the hot rolled steel strip: and (3) accelerating the cooling starting temperature to 950 ℃, the cooling speed to 100 ℃/s and the final cooling temperature to 560 ℃, and cooling the steel coil to room temperature after the steel strip is coiled to obtain the hot-rolled plate strip steel.

The microstructure of the prepared hot-rolled plate strip steel is upper bainite and widmannstatten structure.

The yield strength of the prepared hot rolled strip steel is 570MPa, and the impact toughness at-20 ℃ is 31J.

Although the titanium-boron cored wire is adopted in the comparative example, the components of the titanium-boron cored wire and the oxygen content in the steelmaking process are not properly controlled, and good microstructure type and mechanical property cannot be obtained.

Comparative example 3

step 1: smelting of

Smelting molten iron into molten steel by adopting a converter, tapping when the temperature of the molten steel reaches 1680 ℃, and the mass fraction of carbon in the molten steel is 0.03%, the mass fraction of phosphorus is 0.01%, and the mass fraction of sulfur is 0.01%, and adding silicon, calcium and barium (1: 1:1) into a steel ladle for deoxidation in the tapping process;

step 2: refining and continuous casting

Performing LF refining and VD refining on the tapped molten steel, removing impurities and adjusting temperature and adjusting components by deoxidation and desulfurization in the refining process, wherein the LF refining time is 30min, and the VD refining time is 50 min; carrying out calcium treatment on the molten steel after VD refining; casting the refined molten steel into a slab through a slab caster;

the hot-rolled plate strip steel comprises the following chemical components in percentage by mass: c: 0.16%, Si: 0.2%, Mn: 1.3%, P: 0.01%, S: 0.003%, Al: 0.04%, Ca: 0.002%, O: 0.003%, N: 0.003%, Nb: 0.03%, V: 0.04%, and the balance of Fe and inevitable impurities;

and step 3: hot rolling

Heating the continuous casting plate blank to 1150 ℃ by a hot-conveying and hot-loading device for 120 min; after discharging and descaling the plate blank, performing two-stage controlled rolling by using a roughing mill and a finishing mill, wherein the intermediate blank is subjected to temperature control in the rolling process, the roughing and finishing temperature is 1080 ℃, the finishing and finishing temperature is 820 ℃, and the pass reduction rate is 8-35%, so as to obtain a hot-rolled steel plate;

and 4, step 4: cooling down

Carrying out on-line accelerated cooling on the hot rolled steel plate: and the start cooling temperature of online accelerated cooling is 780 ℃, the cooling speed is 35 ℃/s, the final cooling temperature is 650 ℃, and the steel plate is straightened by a straightening machine and then air-cooled to the room temperature to obtain the hot-rolled plate strip steel.

The microstructure of the prepared hot-rolled plate strip steel is polygonal ferrite and pearlite.

The yield strength of the prepared hot-rolled plate strip steel is 360MPa, and the impact toughness is 225J at the temperature of minus 20 ℃.

This comparative example was subjected to conventional calcium treatment only, without the addition of the fine crystalline elements described in the present invention, and only two-stage low temperature controlled rolling was used to improve texture and properties.

Claims

1. The magnesium-containing fine-grain hot-rolled plate strip steel is characterized by comprising the following chemical components in percentage by mass: c: 0.03-0.25%, Si: 0.05-0.5%, Mn: 0.8-2.0%, P: 0.002-0.03%, S: 0.001-0.03%, Al: 0.003 to 0.07%, Ti: 0.002-0.05%, Mg: 0.001-0.01%, O: 0.001-0.01%, N: 0.003-0.015% and the balance of Fe and inevitable impurities;

the magnesium-containing fine-grain hot-rolled plate strip steel contains Al₂O₃Inclusions, TiO_xInclusions, TiN inclusions, AlN inclusions, MnS inclusions, MgAl₂O₄Inclusions, and other unavoidable inclusions;

wherein the inclusions with a size of 0.03 to 3 μm contain MgAl₂O₄The number of the inclusions is 500 to 3000/mm²(ii) a 50-100% by number of particles of MgAl₂O₄Contains TiO on the surface of the inclusion_xInclusions or/and TiN inclusions as Mg-Ti composite inclusions; 50-100% of the Mg-Ti composite inclusion by particle number contains MnS inclusion on the surface;

the magnesium-containing fine-grain hot-rolled strip steel has two existence modes of TiN and MnS inclusions: exist alone and exist in a compound way with other inclusions; according to the amount of the particles, the TiN compounded with other inclusions accounts for 10-70% of all the TiN; MnS which is present in a composite manner with other inclusions accounts for 10-70% of the total MnS.

2. The magnesium-containing fine-grained hot-rolled sheet strip steel according to claim 1, further comprising the following chemical components in percentage by mass: cr: 0.01-1%, Mo: 0.01-1%, Ni: 0.01-1%, Cu: 0.01-1%, Nb: 0.01-0.2%, V: 0.01-0.2% of one or more of the following components.

3. The magnesium-containing fine-grained hot-rolled sheet strip as claimed in claim 1 or 2, wherein the microstructure type of the magnesium-containing fine-grained hot-rolled sheet strip is ferrite and/or bainite;

the ferrite is in one or more of a polygonal shape, a quasi-polygonal shape, a granular shape or a needle shape, and the bainite is in one or more of a granular shape, a needle shape or a lath shape;

the longitudinal section of the magnesium-containing fine-grain hot rolled plate strip steel is an equal-thickness section or a variable-thickness section;

the yield strength of the magnesium-containing fine-grain hot rolled plate strip steel is 350-750 MPa, and the impact toughness at-20 ℃ is more than or equal to 47J.

4. The method of producing a magnesium containing fine grain hot rolled sheet strip as claimed in claim 1, comprising the steps of:

step 1: smelting

Smelting molten iron and/or steel scrap into molten steel, tapping when the temperature of the molten steel reaches 1600-1700 ℃, the mass fraction of carbon in the molten steel is 0.02-0.15%, the mass fraction of phosphorus is 0.001-0.035%, and the mass fraction of sulfur is 0.001-0.045%, and adding a deoxidizer into a steel ladle for deoxidation in the tapping process; after tapping, the mass percentage content range of dissolved oxygen in the molten steel is 0.001-0.015%;

step 2: refining and continuous casting

Refining the tapped molten steel for 10-60 min; during or after refining, when the mass percentage of dissolved oxygen in the molten steel is 0.0002-0.01%, feeding a cored wire containing magnesium and titanium into the molten steel to generate inclusions containing magnesium and titanium with micron or submicron size, wherein the mass percentage of the dissolved oxygen in the molten steel is 0.0001-0.005%, and the mass percentage of total oxygen is 0.001-0.012%;

and step 3: hot rolling

and 4, step 4: cooling down

And cooling the hot rolled steel plate or strip to obtain the magnesium-containing fine-grain hot rolled plate strip steel.

5. The method for preparing the magnesium-containing fine-grained hot-rolled strip steel according to claim 4, wherein the cored wire containing magnesium and titanium used in the step 2 is a titanium-magnesium-nitrogen cored wire which is prepared by uniformly mixing and filling alloy powder containing titanium, magnesium and nitrogen elements; wherein the grain diameter of the alloy powder containing titanium, magnesium and nitrogen elements is less than or equal to 3 mm; more specifically: the alloy powder comprises the following chemical components in percentage by mass: ti: 10-50%, Mg: 5-40%, N: 1-15%, Al: 0.1 to 10%, Si: 0.1 to 50%, Mn: 0.1-50%, and the balance of iron and impurity elements; the outer diameter of the titanium-magnesium-nitrogen core-spun yarn is 8-13 mm; the wire feeding speed of the titanium-magnesium-nitrogen core-spun wire is 80-200 m/min.

6. The method for preparing the magnesium-containing fine-grained hot-rolled strip steel according to claim 4, wherein in the step 4, the cooling is one of natural cooling in air or on-line accelerated cooling, and when the on-line accelerated cooling is adopted, the start cooling temperature is 800-1100 ℃, the cooling rate is 10-200 ℃/s, and the final cooling temperature is 400-750 ℃.