阅读说明：本技术 一种酸洗用低碳热轧窄带钢氧化铁皮控制工艺 (Control process for iron scale of low-carbon hot-rolled narrow strip steel for pickling ) 是由 梁云科 李玉明 安韶华 吴德贵 时晓杰 曹留英 郭朋 杨春伟 徐宁 于 2020-12-29 设计创作，主要内容包括：本发明涉及冶金技术领域,尤其涉及一种酸洗用低碳热轧窄带钢氧化铁皮控制工艺。所述带钢宽度小于600mm；其特征在于,该工艺路线包括：冶炼阶段调整带钢化学成分→热送矩形坯→铸坯加热→炉后高压水一次除鳞→粗轧及粗除鳞→中间坯辊道减少氧化保温→精轧及精除鳞→层流冷却→高速卷取→自然冷却。本发明适用于3.0mm及以下厚度的酸洗类深加工薄带产品,在酸洗速度120米/分,盐酸浓度25％,温度60～80℃的工艺条件下氧化铁皮全部去除,无麻点、麻坑缺陷的发生,成材率99.2％及以上。(The invention relates to the technical field of metallurgy, in particular to a process for controlling iron scale of low-carbon hot-rolled narrow strip steel for pickling. The width of the strip steel is less than 600 mm; the method is characterized in that the process route comprises the following steps: adjusting the chemical components of the strip steel in the smelting stage → hot delivery of the rectangular blank → heating of the casting blank → one-time descaling of high-pressure water behind the furnace → rough rolling and rough descaling → reduction of oxidation and heat preservation of an intermediate blank roller way → finish rolling and fine descaling → laminar cooling → high-speed coiling → natural cooling. The method is suitable for pickling deep-processing thin strip products with the thickness of 3.0mm or less, iron scales are completely removed under the technological conditions of pickling speed of 120 m/min, hydrochloric acid concentration of 25% and temperature of 60-80 ℃, no pockmark or pockmark defects occur, and the yield is 99.2% or more.)

1. A control process for iron scale of low-carbon hot-rolled narrow strip steel for pickling is disclosed, wherein the width of the strip steel is less than 600 mm; the method is characterized in that the process route comprises the following steps: adjusting the chemical components of the strip steel in the smelting stage → hot delivery of the rectangular blank → heating of the casting blank → one-time descaling of high-pressure water behind the furnace → rough rolling and rough descaling → reduction of oxidation and heat preservation of an intermediate blank roller way → finish rolling and fine descaling → laminar cooling → high-speed coiling → natural cooling.

2. The process for controlling the scale of the low-carbon hot-rolled narrow strip steel for pickling as claimed in claim 1, wherein the adjusted strip steel comprises the following chemical components: 0.05% -0.20% of C; si is 0.07-0.25%; mn is 0.20-0.60%; p is less than or equal to 0.035%; s is less than or equal to 0.040%; cr is less than or equal to 0.30 percent; ni is less than or equal to 0.30 percent; cu is less than or equal to 0.30 percent; as is less than or equal to 0.08 percent, and the balance is Fe.

3. The process for controlling the iron scale of the low-carbon hot-rolled narrow strip steel for pickling as claimed in claim 1, wherein the casting blank in the continuous casting stage is a rectangular hot-delivery blank, the thickness of the casting blank is 150-165 mm, the width of the casting blank is 330-380 mm, and the temperature of the casting blank is 400-800 ℃.

4. The process for controlling the scale of the low-carbon hot-rolled narrow strip steel for pickling as claimed in claim 1, wherein the casting blank is heated by a double-heat-storage walking beam type three-section heating furnace, wherein the temperature of the heating section is controlled to be 1100-1250 ℃, the temperature of the soaking section is controlled to be 1200-1280 ℃, the total heating time is 65-90 minutes, the furnace pressure is controlled to be less than or equal to 25Pa, the air-fuel ratio is controlled to be 0.60-0.75, and the thickness of the primary scale is less than or equal to 1 mm.

5. The control process of the iron scale of the low-carbon hot-rolled narrow strip steel for pickling as claimed in claim 1, wherein 3-pass vertical rolling and 5-pass flat rolling are adopted for the rough rolling for 8-pass continuous rolling, and the initial rolling temperature of the rough rolling is 1080-1160 ℃; and/or performing high-pressure water descaling after the rough rolling and vertical rolling mill, wherein the descaling pressure is 10-18 MPa.

6. The process for controlling the scale of the low-carbon hot-rolled narrow strip steel for pickling according to claim 1, wherein the process for reducing oxidation and maintaining the temperature of the intermediate billet roller way comprises arranging a cover for reducing oxidation and maintaining the temperature above the intermediate billet roller way between the rough rolling outlet and the finish rolling inlet.

7. The process for controlling the scale of the low-carbon hot-rolled narrow strip steel for pickling as claimed in claim 1, wherein the finish rolling adopts 11 passes of continuous rolling, including 2 passes of vertical rolling and 9 passes of flat rolling, the start temperature of the finish rolling is 1030-1110 ℃, and the finish rolling speed is controlled to be 10.5-16.0 m/s according to different specifications.

8. The process for controlling the iron scale of the low-carbon hot-rolled narrow strip steel for pickling as claimed in claim 1, wherein a laminar cooling process is adopted after finish rolling, and the temperature of laminar flow is 870-950 ℃; starting 4-11 cooling sections within the range of the strip steel thickness of 2-4.5 mm; the cooling speed is 60-150 ℃/s, and the coiling temperature is controlled to be 600-680 ℃.

9. The process for controlling the scale of the low-carbon hot-rolled narrow strip steel for pickling as claimed in claim 1, wherein the coiling speed in the high-speed coiling process is matched with the speed of a finish-rolling nine-pass mill, namely the final rolling speed, the coiling tension is controlled to be 20-28 KN, and the diameter of a winding drum is 492-520 mm.

10. The process for controlling the scale of the low-carbon hot-rolled narrow strip steel for pickling as claimed in claim 1, wherein the thickness of the scale of the narrow strip steel prepared by the process is less than or equal to 10 μm, and the fluctuation value of the thickness of the scale along the cross section is less than or equal to 3 μm.

Technical Field

The invention relates to the technical field of metallurgy, in particular to a process for controlling iron scale of low-carbon hot-rolled narrow strip steel for pickling.

Background

The hot-rolled narrow strip steel generally refers to strip steel with the width less than 600mm, and is mainly used for deep processing of welded pipes, cold-formed steel, hardware, stamping parts and the like. With the continuous progress of narrow strip steel production equipment and technology, the surface quality, the dimensional precision and the mechanical property of the narrow strip steel are obviously improved, and the requirements of high value-added products for pickling, such as cold-rolled products, on the narrow strip steel are increased.

The pickling type deep processing product has strict requirements on the surface quality, the dimensional precision and the mechanical property of the narrow band steel, and the most important is that the quality of the scale of the narrow band steel is strictly required. Firstly, the thickness of the iron scale of the strip steel is required to be as thin as possible, secondly, the uniformity of the thickness of the iron scale is required, the thickness deviation is as small as possible, and thirdly, the iron scale is required not to have the press-in defect. For good iron scale quality, pickling enterprises can reduce the acid consumption, improve the pickling speed and the yield, ensure the quality of a coating, and reduce the production cost of the enterprises and the pollution degree to the environment, so that the quality of the iron scale of the strip steel becomes one of the marks for measuring the quality of narrow strip steel produced by the enterprises.

The production process of the conventional narrow strip steel product comprises the steps of heating a casting blank → high-pressure water descaling → rough rolling reversible rolling → finish rolling → torsion → guide groove cooling → snake-shaped oscillation → plate chain transportation → vertical coiling → packing → spray marking.

Due to the limitation of high rolling speed and low cooling water pressure in the guide groove cooling, the temperature drop amplitude is generally not more than 100 ℃, namely the temperature is cooled to be more than 800 ℃, and the effect of thinning the iron scale is far from being achieved. Snakelike shock forms snakelike cover on dull and stereotyped conveying chain, and the mutual lapped position of belted steel cools off slowly, and not lapped position cooling block, and the shortcoming is that the cooling is inhomogeneous, and the cold rate is uncontrollable, and the ribbon steel oxide scale thickness that obtains is big and inhomogeneous, and maximum thickness can reach 30 ~ 40 mu m, and inhomogeneous degree (thickness deviation) can reach 5 ~ 15 mu mm, can take place the condition that the oxide scale drops in advance simultaneously to produce new fine and close oxide scale. In the vertical coiling, because the coiling machine and the five-roller straightener form tension, steel flying cannot be caused, a lower coiling speed is required and is generally controlled to be below 10.0m/s, so that the oxidation time of the strip steel is too long, and the reduction of the thickness of an oxide scale is not favorable.

Under the conventional narrow strip steel process conditions, pickling deep processing enterprises can only reduce the pickling speed (increase the pickling time) or increase the acid concentration to remove the iron scale, and even reduce the pickling speed and increase the acid concentration, the iron scale cannot be effectively removed, so that pit and pit defects are generated, and the pickling quality cannot be guaranteed.

Disclosure of Invention

Aiming at the problems in the prior art, the control process of the iron scale of the low-carbon hot-rolled narrow strip steel for pickling is provided.

The technical scheme adopted by the invention for solving the technical problems in the prior art is as follows:

a control process for iron scale of low-carbon hot-rolled narrow strip steel for pickling is disclosed, wherein the width of the strip steel is less than 600 mm; the method is characterized in that the process route comprises the following steps: adjusting the chemical components of the strip steel in the smelting stage → hot delivery of the rectangular blank → heating of the casting blank → one-time descaling of high-pressure water behind the furnace → rough rolling and rough descaling → reduction of oxidation and heat preservation of an intermediate blank roller way → finish rolling and fine descaling → laminar cooling → high-speed coiling → natural cooling.

As a further optimized technical scheme of the invention, the adjusted strip steel comprises the following chemical components: 0.05% -0.20% of C; si is 0.07-0.25%; mn is 0.20-0.60%; p is less than or equal to 0.035%; s is less than or equal to 0.040%; cr is less than or equal to 0.30 percent; ni is less than or equal to 0.30 percent; cu is less than or equal to 0.30 percent; as is less than or equal to 0.08 percent, and the balance is Fe. The preferred chemical composition takes into account harmful chemical elements that are detrimental to the removal of scale: si, Ni, Cu and As are subjected to multiple experiments, and the maximum content of the elements is limited on the basis of not influencing other properties of the strip steel.

As a further optimized technical scheme, a casting blank in a continuous casting stage is a hot-delivery rectangular blank, the thickness of the casting blank is 150-165 mm, the width of the casting blank is 330-380 mm, and the temperature of the casting blank is 400-800 ℃. The hot blank conveying can reduce the heating temperature, improve the rolling rhythm and reduce the oxidation of the casting blank.

As a further optimized technical scheme, the casting blank is heated by a double-heat-storage walking beam type three-section heating furnace, wherein the temperature of a heating section is controlled to be 1100-1250 ℃, the temperature of a soaking section is controlled to be 1200-1280 ℃, the total heating time is 65-90 minutes, the furnace pressure is controlled to be less than or equal to 25Pa, the air-fuel ratio is controlled to be 0.60-0.75, and the thickness of primary iron scale is less than or equal to 1 mm;

as a further optimized technical scheme, the rough rolling adopts 8-pass continuous rolling of 3-pass vertical rolling and 5-pass flat rolling, and the initial rolling temperature of the rough rolling is 1080-1160 ℃.

As a further optimized technical scheme of the invention, high-pressure water descaling is carried out after a rough rolling-vertical rolling mill for rough descaling, the descaling pressure is 10-18 MPa, and the good descaling effect can be ensured.

As a further optimized technical scheme, the intermediate billet roller way oxidation reduction and heat preservation process comprises the step of arranging an oxidation reduction and heat preservation cover above the intermediate billet roller way between a rough rolling outlet and a finish rolling inlet, so that the temperature drop of an intermediate billet and the thickness of secondary iron scale can be effectively reduced, and the subsequent process descaling is facilitated.

As a further optimized technical scheme, the finish rolling adopts 11-pass continuous rolling of 2-pass vertical rolling and 9-pass flat rolling, the start rolling temperature of the finish rolling is 1030-1110 ℃, the finish rolling speed is controlled to be 10.5-16.0 m/s according to different specifications, the subsequent procedures can be ensured to be rapidly cooled, and the generation of three-time iron scale is reduced;

the fine descaling is to carry out high-pressure water descaling after the strip steel passes through a fine rolling vertical mill, and the descaling pressure is 8.0-15.0 MPa; and cooling the finish rolling roller by water, wherein the pressure of the cooling water is 0.4-0.6 MPa.

As a further optimized technical scheme, a laminar cooling process is adopted after finish rolling, and the temperature of the laminar flow is 870-950 ℃; starting 4-11 cooling sections within the range of the strip steel thickness of 2-4.5 mm; the cooling speed is 60-150 ℃/s, and the coiling temperature is controlled to be 600-680 ℃.

As a further optimized technical scheme of the invention, the coiling speed in the high-speed coiling process is matched with the speed of a finish rolling nine-flat mill (final rolling speed), the coiling tension is controlled to be 20-28 KN, and the diameter of a winding drum is 492-520 mm.

As a further optimized technical scheme of the invention, the thickness of the iron scale of the narrow strip steel prepared by the process is less than or equal to 10 microns, and the fluctuation value of the thickness of the iron scale along the cross section is less than or equal to 3 microns.

The invention has the advantages and positive effects that:

the invention solves the problem that the thickness of the scale of the strip steel with the width less than 600mm is larger in the production process, and the process control is carried out by adjusting the chemical components of the strip steel in the smelting stage, hot feeding a rectangular billet, heating a casting blank, carrying out high-pressure water one-time descaling after the furnace, carrying out rough rolling and rough descaling, reducing oxidation and heat preservation of an intermediate billet roller way, carrying out finish rolling and fine descaling, carrying out laminar cooling, carrying out high-speed coiling and naturally cooling. The method is suitable for pickling deep-processing thin strip products with the thickness of 3.0mm or less, iron scales are completely removed under the technological conditions of pickling speed of 120 m/min, hydrochloric acid concentration of 25% and temperature of 60-80 ℃, no pockmark or pockmark defects occur, and the yield is 99.2% or more.

Drawings

FIG. 1 is a schematic view of the microstructure of the oxide scale thickness in example 1 of the present invention;

FIG. 2 is a schematic view of the microstructure of the oxide scale thickness in example 2 of the present invention;

FIG. 3 is a schematic microstructure of the thickness of the scale in example 3 of the present invention;

FIG. 4 is a cross-sectional view of the heat retention cover of the present invention.

Wherein, 1, hoisting the device; 2. a thermal insulation material; 3. a protective cover housing; 4. a heat-resistant steel plate; 5. and (4) bolts.

Detailed Description

In order to further understand the contents, features and effects of the present invention, the following examples are illustrated, and the following detailed descriptions are given:

the invention discloses a process for controlling iron scale of low-carbon hot-rolled narrow strip steel for pickling, which comprises the following steps: adjusting the chemical components of the strip steel in the smelting stage → hot delivery of the rectangular blank → heating of the casting blank → one-time descaling of high-pressure water behind the furnace → rough rolling and rough descaling → reduction of oxidation and heat preservation of an intermediate blank roller way → finish rolling and fine descaling → laminar cooling → high-speed coiling → natural cooling.

The specific technical measures comprise:

1. adjusting the chemical components of the strip steel: according to the pickling characteristics and requirements of the iron scale of the low-carbon hot-rolled narrow strip steel, the chemical components are preferably designed as shown in the table 1.

Table 1 chemical composition units: (%)

The preferred chemical composition takes into account harmful chemical elements that are detrimental to the removal of scale: si, Ni, Cu and As are subjected to multiple experiments, and the maximum content of the elements is limited on the basis of not influencing other properties of the strip steel.

2. The casting blank in the continuous casting stage adopts: the method comprises the following steps of carrying out hot delivery on a rectangular blank, wherein the thickness of the blank is 150-165 mm, the width of the blank is 330-380 mm, the temperature of the blank is 400-800 ℃, and the hot delivery of the blank can reduce the heating temperature, improve the rolling rhythm and reduce the oxidation of the blank.

3. And (3) heating the casting blank by adopting a double-heat-storage walking beam type three-section heating furnace, wherein the temperature of a heating section is controlled to be 1100-1250 ℃, the temperature of a soaking section is controlled to be 1200-1280 ℃, the total heating time is 65-90 minutes, the furnace pressure is controlled to be less than or equal to 25Pa, the air-fuel ratio is controlled to be 0.60-0.75, and the thickness of the primary iron scale is less than or equal to 1 mm.

4. And (3) descaling once by using high-pressure water after the furnace, wherein the descaling pressure is 12-20 MPa, and the good descaling effect of the steel billet is ensured.

5. Rough rolling and rough descaling (secondary descaling), wherein the rough rolling adopts 8-pass continuous rolling of 3-pass vertical rolling and 5-pass flat rolling, the initial rolling temperature of the rough rolling is 1080-1160 ℃, the rough descaling adopts high-pressure water descaling after the rough rolling and the vertical rolling, the descaling pressure is 10-18 MPa, the descaling effect is good, the rough rolling roller is cooled by water, the cooling water pressure is 0.4-0.6 MPa, the roller oxide film is ensured to be intact, and the roller oxide film is prevented from being pressed in.

6. The process for reducing oxidation and preserving heat of the intermediate billet roller way comprises the steps of arranging an oxidation-reducing heat-preserving cover above the intermediate billet roller way between a rough rolling outlet and a finish rolling inlet; preferably, as shown in fig. 4, the heat-insulating cover is a trapezoidal shell structure arranged above the intermediate billet roller way between the rough rolling outlet and the finish rolling inlet; the heat-insulation cover consists of 16 cover bodies, each cover body is 4.4m long and 70.4m in total length, a heat-resistant steel plate 4 is arranged on the inner side of the protection cover, a heat-insulation material 2 made of an aluminum silicate fiber felt is arranged between the heat-resistant steel plate 4 and the protection cover shell 3, and the protection cover shell, the heat-insulation material and the heat-resistant steel plate are connected into a whole through a plurality of bolts 5; a hoisting device 1 is arranged above the protective cover. The aluminum silicate fiber felt has high temperature resistance, and the maximum use temperature can reach 1300 ℃; the heat conductivity is low, the heat insulation performance is good, and when the aluminum silicate product is used under the same condition, the heat conductivity is lower than that of other heat insulation materials by more than 30%.

The intermediate billet can be cooled to less than 20 ℃ by walking on the roller way, the thickness of the secondary oxide scale is less than 0.5mm, the temperature drop of the intermediate billet and the thickness of the secondary oxide scale can be effectively reduced, and the descaling of the subsequent process is facilitated.

7. Finish rolling and fine descaling (tertiary descaling), wherein the finish rolling adopts 11 passes of continuous rolling of 2 passes of vertical rolling and 9 passes of flat rolling, the start temperature of the finish rolling is 1030-1110 ℃, the finish rolling speed is controlled at 10.5-16.0 m/s according to different specifications, the subsequent procedure can be ensured to be rapidly cooled, and the generation of tertiary scale is reduced; the fine descaling is carried out by high-pressure water descaling after a finish rolling vertical mill, the descaling pressure is 8.0-15.0 MPa, the good descaling effect can be ensured, the finish rolling roller is cooled by water, the cooling water pressure is 0.4-0.6 MPa, the roller oxide film can be ensured to be intact, and the roller oxide film is prevented from being pressed in.

8. A laminar cooling process, wherein the laminar cooling process is adopted after finish rolling, the temperature of the laminar flow is 870-950 ℃, 4-11 cooling sections are started within the range of 2-4.5mm of strip steel thickness according to different specifications; the cooling speed is 60-150 ℃/s, and the coiling temperature is controlled to be 600-680 ℃.

9. The high-speed coiling process has the advantages that the coiling speed is matched with the speed (final rolling speed) of a finish rolling nine-flat mill when tension is stably established, the high-speed coiling can ensure that the generation time of the rolled iron scale is shortened, and the thickness of the iron scale is reduced. The coiling tension is controlled to be 20-28 KN according to different specifications, so that the layers and the coiling are guaranteed to be compact, the contact between the interior of the strip steel and air is reduced, and the thickness of iron scale is reduced; the diameter of the winding drum is 492-520mm, so that the winding time of each layer is short, and the generated iron scale is less.

10. And naturally cooling, namely naturally cooling the coiled steel strip after coiling.

11. The finished strip steel product has the specification of 2.0-4.5 mm in thickness and 335-438 mm in width, and is suitable for pickling deep-processing thin strip products with the thickness of 3.0mm and below.

12. The thickness of the scale of the narrow band steel is less than or equal to 10 mu m, and the fluctuation value of the thickness of the scale along the cross section is 3 mu m.

The method is suitable for pickling deep-processing thin strip products with the thickness of 3.0mm or less, iron scales are completely removed under the technological conditions of pickling speed of 120 m/min, hydrochloric acid concentration of 25% and temperature of 60-80 ℃, no pockmark or pockmark defects occur, and the yield is 99.2% or more.

Example 1

Specification of a finished strip steel product: the thickness is 2.0mm, and the width is 365 mm.

1. Chemical composition

Table 2 chemical composition units: (%)

C	Si	Mn	P	S	Cr	Ni	Cu	As	Fe
										0.06	0.10	0.25	0.015	0.024	0.08	0.01	0.02	0.008	Balance of

2. The preferable casting blank adopts: and (3) hot-conveying a rectangular blank, wherein the thickness of the blank is 150mm, the width of the blank is 330mm, and the temperature of the blank is 400-800 ℃.

3. And (3) heating the casting blank by adopting a double-heat-storage walking beam type three-section heating furnace, wherein the temperature of a heating section is controlled to be 1100-1250 ℃, the temperature of a soaking section is controlled to be 1200-1280 ℃, the total heating time is 65-90 minutes, the furnace pressure is controlled to be less than or equal to 25Pa, the air-fuel ratio is controlled to be 0.60-0.65, and the thickness of the primary iron scale is less than or equal to 1 mm.

4. And (4) carrying out primary descaling by high-pressure water after the furnace, wherein the descaling pressure is 12-20 MPa.

5. Rough rolling and rough descaling (secondary descaling), wherein the rough rolling adopts 8-pass continuous rolling of 3-pass vertical rolling and 5-pass flat rolling, the starting temperature of the rough rolling is 1080-1160 ℃, the rough descaling adopts high-pressure water descaling after the rough rolling and the vertical rolling, the descaling pressure is 10-18 MPa, the rough rolling roller is cooled by water, and the cooling water pressure is 0.4-0.6 MPa.

6. The process for reducing oxidation and preserving heat of the intermediate billet roller way is characterized in that an oxidation reduction and preserving heat cover is arranged above the intermediate billet roller way between a rough rolling outlet and a finish rolling inlet, so that the temperature of the intermediate billet can be reduced to be less than 20 ℃, and the thickness of a secondary oxide scale is less than 0.5 mm.

7. And (3) finish rolling and fine descaling (tertiary descaling), wherein the finish rolling adopts 11-pass continuous rolling of 2-pass vertical rolling and 9-pass flat rolling, the start rolling temperature of the finish rolling is 1030-1110 ℃, the final rolling speed is controlled at 11.5-16.0 m/s, the fine descaling adopts high-pressure water descaling after a finish rolling-vertical rolling mill, the descaling pressure is 8.0-15.0 MPa, the finish rolling roller is cooled by water, and the cooling water pressure is 0.4-0.6 MPa.

8. And (3) a laminar cooling process is adopted after finish rolling, the laminar cooling process is carried out, the temperature of the laminar flow is 870-940 ℃, 5-8 cooling sections are started, the cooling speed is 110-134 ℃/s, and the coiling temperature is 600-670 ℃.

9. The high-speed coiling process has the coiling speed matched with the speed (final rolling speed) of a finish rolling nine-flat rolling mill when the tension is stably established, the coiling tension is controlled at 21KN, and the diameter 492-520mm of a winding drum.

10. And naturally cooling, namely naturally cooling the coiled steel strip after coiling.

11. As shown in figure 1, the thickness of the iron scale is 7.69-7.92 μm, and the fluctuation value of the thickness of the iron scale along the cross section is 0.23 μm.

Example 2

Specification of a finished strip steel product: the thickness is 3.70mm, and the width is 415 mm.

1. Chemical composition of strip steel

Table 3 chemical composition units: (%)

C	Si	Mn	P	S	Cr	Ni	Cu	As	Fe
										0.15	0.20	0.58	0.028	0.035	0.11	0.12	0.10	0.010	Balance of

2. The preferable casting blank adopts: and (3) hot-conveying a rectangular blank, wherein the thickness of the blank is 165mm, the width of the blank is 380mm, and the temperature of the blank is 400-800 ℃.

3. And (3) heating the casting blank by adopting a double-heat-storage walking beam type three-section heating furnace, wherein the temperature of a heating section is controlled to be 1100-1250 ℃, the temperature of a soaking section is controlled to be 1200-1280 ℃, the total heating time is 65-90 minutes, the furnace pressure is controlled to be less than or equal to 25Pa, the air-fuel ratio is controlled to be 0.60-0.65, and the thickness of the primary iron scale is less than or equal to 1 mm.

4. And (4) carrying out primary descaling by high-pressure water after the furnace, wherein the descaling pressure is 12-20 MPa.

5. Rough rolling and rough descaling (secondary descaling), wherein the rough rolling adopts 8-pass continuous rolling of 3-pass vertical rolling and 5-pass flat rolling, the starting temperature of the rough rolling is 1080-1160 ℃, the rough descaling adopts high-pressure water descaling after the rough rolling and the vertical rolling, the descaling pressure is 10-18 MPa, the rough rolling roller is cooled by water, and the cooling water pressure is 0.4-0.6 MPa.

6. The process comprises the steps of reducing oxidation and heat preservation of the intermediate billet, reducing oxidation and heat preservation of an intermediate billet roller way, arranging an oxidation and heat preservation reducing cover above the intermediate billet roller way between a rough rolling outlet and a finish rolling inlet, and reducing the temperature of the intermediate billet to be less than 20 ℃ and the thickness of secondary iron scale to be less than 0.5 mm.

7. And (3) finish rolling and finish descaling (tertiary descaling), wherein the finish rolling adopts 11 passes of continuous rolling of 2 passes of vertical rolling and 9 passes of horizontal rolling, the finish rolling starting temperature is 1030-1110 ℃, the finish rolling speed is controlled at 11.5-15.5 m/s according to different specifications, the finish descaling adopts high-pressure water descaling after a finish rolling-vertical rolling mill, the descaling pressure is 8.0-15.0 MPa, the finish rolling roller is cooled by water, and the cooling water pressure is 0.4-0.6 MPa.

8. And (3) a laminar cooling process is adopted after finish rolling, the laminar cooling process is carried out, the temperature of the laminar flow is 870-940 ℃, 8-11 cooling sections are started, the cooling speed is 80.5-102 ℃/s, and the coiling temperature is 600-670 ℃.

9. The high-speed coiling process has the coiling speed matched with the speed (finishing speed) of a finish-rolling nine-flat rolling mill when the tension is stably established, the coiling tension is controlled at 25KN, and the diameter 492-520mm of a winding drum.

10. And naturally cooling, namely naturally cooling the coiled steel strip after coiling.

11. As shown in FIG. 2, the thickness of the iron scale is 6.81-8.35 μm, and the fluctuation value of the thickness of the iron scale along the cross section is 1.54 μm.

Example 3

Specification of a finished strip steel product: the thickness is 4.4mm and the width is 435 mm.

1. Chemical composition

Table 4 chemical composition units: (%)

C	Si	Mn	P	S	Cr	Ni	Cu	As	Fe
										0.06	0.23	0.46	0.024	0.034	0.07	0.15	0.12	0.012	Balance of

2. The preferable casting blank adopts: and (3) hot-conveying a rectangular blank, wherein the thickness of the blank is 165mm, the width of the blank is 380mm, and the temperature of the blank is 400-800 ℃.

3. And (3) heating the casting blank by adopting a double-heat-storage walking beam type three-section heating furnace, wherein the temperature of a heating section is controlled to be 1100-1250 ℃, the temperature of a soaking section is controlled to be 1200-1280 ℃, the total heating time is 65-90 minutes, the furnace pressure is controlled to be less than or equal to 25Pa, the air-fuel ratio is controlled to be 0.60-0.65, and the thickness of the primary iron scale is less than or equal to 1 mm.

4. And (4) carrying out primary descaling by high-pressure water after the furnace, wherein the descaling pressure is 12-20 MPa.

5. Rough rolling and rough descaling (secondary descaling), wherein the rough rolling adopts 8-pass continuous rolling of 3-pass vertical rolling and 5-pass flat rolling, the starting temperature of the rough rolling is 1080-1160 ℃, the rough descaling adopts high-pressure water descaling after the rough rolling and the vertical rolling, the descaling pressure is 10-18 MPa, the rough rolling roller is cooled by water, and the cooling water pressure is 0.4-0.6 MPa.

6. The process comprises the steps of reducing oxidation and heat preservation of the intermediate billet, reducing oxidation and heat preservation of an intermediate billet roller way, arranging an oxidation and heat preservation reducing cover above the intermediate billet roller way between a rough rolling outlet and a finish rolling inlet, and reducing the temperature of the intermediate billet to be less than 20 ℃ and the thickness of secondary iron scale to be less than 0.5 mm.

7. And (3) finish rolling and finish descaling (tertiary descaling), wherein the finish rolling adopts 11 passes of continuous rolling of 2 passes of vertical rolling and 9 passes of horizontal rolling, the finish rolling starting temperature is 1030-1110 ℃, the finish rolling speed is controlled at 10.5-12.7 m/s according to different specifications, the finish descaling adopts high-pressure water descaling after a finish rolling-vertical rolling mill, the descaling pressure is 8.0-15.0 MPa, the finish rolling roller is cooled by water, and the cooling water pressure is 0.4-0.6 MPa.

8. And (3) a laminar cooling process is adopted after finish rolling, the laminar cooling process is carried out, the temperature of the laminar flow is 880-950 ℃, 5-8 cooling sections are started, the cooling speed is 70-92 ℃/s, and the coiling temperature is 610-680 ℃.

9. The high-speed coiling process has the coiling speed matched with the speed (finishing speed) of a finish-rolling nine-flat rolling mill when the tension is stably established, the coiling tension is controlled at 27KN, and the diameter 492-520mm of a winding drum.

10. And naturally cooling, namely naturally cooling the coiled steel strip after coiling.

11. As shown in FIG. 3, the thickness of the iron scale is 8.35-9.45 μm, and the fluctuation value of the thickness of the iron scale along the cross section is 1.1 μm.