CN112742880A

CN112742880A - Method for controlling head and tail shapes of narrow-specification steel plates through local temperature difference

Info

Publication number: CN112742880A
Application number: CN201911049451.3A
Authority: CN
Inventors: 孔伟; 王全胜
Original assignee: Baoshan Iron and Steel Co Ltd
Current assignee: Baoshan Iron and Steel Co Ltd
Priority date: 2019-10-31
Filing date: 2019-10-31
Publication date: 2021-05-04
Anticipated expiration: 2039-10-31
Also published as: CN112742880B

Abstract

The invention discloses a method for controlling the head and tail shapes of narrow-specification steel plates through local temperature difference, which comprises the steps of realizing local cooling of rolled pieces in a descaling mode and local cooling of single-pipe water flow in the middle of a roller way; the descaling mode realizes local cooling of rolled pieces and comprises the following steps: 1) a frame descaling system is arranged on the heavy and medium plate mill; 2) the middle part of the rolled piece in the width direction is cooled in the full length direction by using descaling water of a frame descaling system; the method for locally cooling the middle part of the roller way by the single pipe water flow comprises the following steps: 1) arranging a water flow device in the middle of a roller way of the heavy and medium plate mill; 2) and cooling the middle part of the head and the tail of the rolled piece in the width direction by using cooling water of the water flow device. The temperature distribution of the rolled piece is changed through the water system, different extensions are realized by changing the deformation resistance of the local matrix of the rolled piece, and the plane shape is improved.

Description

Method for controlling head and tail shapes of narrow-specification steel plates through local temperature difference

Technical Field

The invention relates to a hot steel plate rolling control technology, in particular to a method for controlling the head and tail shapes of a narrow-specification steel plate through local temperature difference, which is particularly suitable for a medium plate production line needing to control head and tail fillets of the steel plate.

Background

In the hot rolling process of the steel industry, a plate blank with larger thickness is rolled into a steel plate with thinner thickness by a roller. The head and tail of the steel plate are uneven in extension, the volume extension restriction of the width middle part of the head and tail is small, and the extension amount is more than that of the edge part, so that the abnormal shape of the head and tail (the protruding shape of the width middle part of the head and tail is like a tongue as shown in fig. 1) is caused, and the user can be delivered after the cutting process is added. Therefore, the shape of the head and the tail of the steel plate is one of the main factors influencing the yield, and a plurality of hot rolling processes are controlled, especially in the field of thick plates. The steel rolling production lines at home and abroad adopt a plurality of plane shape control methods, and most of the steel rolling production lines adopt three types of steel rotating strategy optimization deformation, thickness difference optimization deformation and vertical roll (large side pressure) side pressure optimization deformation, and a small amount of patents for adjusting the shape of a plate blank supplied material.

Type one, steel conversion strategy optimization deformation:

the steel rolling is one of the main characteristics of a medium plate mill, the extension sequence of four sides can be changed by the steel rolling, so that the plate shape is improved, and the traditional longitudinal rolling method, the traditional transverse rolling method and the traditional comprehensive rolling method belong to the type. Related patent applications are: a control method (CN102974624B) for the edge plane shape of the pipeline steel with large width expansion ratio and high strength grade, and a thick plate rolling method (CN 102886381B).

The above 2 patents teach the improvement of the planar shape of rolled steel sheet by optimization of the turning of the steel in the case of rolling wide gauge steel sheet and short slab.

Type two, thickness difference optimization deformation:

in the last 60-70 th century, such as MAS rolling method (Mizushima Automatic plant View Pattern Con-trol System) and edging method, various methods are developed by Japan steel enterprises, deformation optimization is realized by changing local thickness of rolled pieces, and steel plate plane shape is optimized, and various enterprises in various countries develop various methods based on the methods. Related patent applications are: WIDTHWISE ROLLING METHOD FOR PREVENTING CAMBER OF PLATE (KR20010083693), Method of plate rolling and equipment thermally (US19820414838) (JP19790089567), a Method of controlling a wide plate plane shape based on crown control (CN 104858243B).

Type three, vertical roll (large side pressure) side pressure optimization deformation:

this type is a method of improving the uniformity of the head and tail shape and width by changing the local width of the rolled piece mainly by vertical rolls or a large side pressure short stroke. The method is widely used in a hot rolling production line, and a medium plate production line is also used to a certain extent. Related patent applications are: the method for controlling the head and tail shapes of the continuous casting slabs (CN103252347A) and the method for controlling the dynamic short stroke of the head and tail widths of the slabs (CN103934279B) reduce the head and tail cutting amount of the hot-rolled intermediate slabs.

The development of the three types of plane shape control technologies is very mature, and in the aspect of head and tail shape control, the MAS (Mizushima Automatic plant View Pattern Con-trol System) rolling method and similar technologies thereof and the vertical roll edging method are widely applied to various large hot rolling (particularly medium plate) and have very good effects. These techniques are all implemented to change the three-dimensional dimensions of the rolled piece at the early stage of rolling, thereby improving the head-tail shape. The method has higher requirements on equipment investment and a model control system. The narrow-specification (the width is less than or equal to 2200mm, the broadening ratio is less than or equal to 1.2) steel plate has the advantages of large extension ratio (more than or equal to 10), small rolling reduction in the width direction, high requirement on the precision of a rolling model, large head-tail fillet length, and limited effect improvement by utilizing the above modes.

Disclosure of Invention

Aiming at the defects of the head and the tail of the steel plate in the prior art, the invention aims to provide a method for controlling the head and the tail of the narrow-specification steel plate through local temperature difference, the temperature distribution of a rolled piece is changed through a water system, different extensions are realized by changing the deformation resistance of a local matrix of the steel plate, and the plane shape is improved.

In order to achieve the purpose, the invention adopts the following technical scheme:

a method for controlling the head and tail shapes of narrow-specification steel plates through local temperature difference comprises the steps of realizing local cooling of rolled pieces and local cooling of single-pipe water flow in the middle of a roller way in a descaling mode;

the descaling mode realizes local cooling of rolled pieces and comprises the following steps:

1) a frame descaling system is arranged on the heavy and medium plate mill;

2) the middle part of the rolled piece in the width direction is cooled in the full length direction by using descaling water of a frame descaling system;

the method for locally cooling the middle part of the roller way by the single pipe water flow comprises the following steps:

1) arranging a water flow device in the middle of a roller way of the heavy and medium plate mill;

2) and cooling the middle part of the head and the tail of the rolled piece in the width direction by using cooling water of the water flow device.

Step 2) of realizing local cooling of the rolled piece in the descaling mode specifically comprises the following steps:

the method comprises the steps of firstly determining the pass of local cooling of a rolled piece, carrying out local cooling before the first pass of full longitudinal rolling, rotating the rolled piece by 90 degrees before the full longitudinal rolling, transporting the rolled piece to the lower part of a frame descaling system after parallel rolling in the width direction, keeping the rolled piece in a static state, starting descaling water for cooling, removing the rolled piece after cooling the upper area of the rolled piece, rotating by 90 degrees again, and carrying out longitudinal rolling with the head and the tail of the rolled piece as the rolling direction.

And the descaling water cooling time is 10-90 s.

The rolled piece upper area is divided into: and dividing an edge region, a middle region and an edge region in sequence according to the width direction of the rolled piece.

And after the temperature of the upper middle area of the rolled piece is reduced by 30-200 ℃, moving out the rolled piece.

Step 2) of locally cooling the single pipe water flow in the middle of the roller way specifically comprises the following steps:

firstly, determining the pass of local cooling of a rolled piece, carrying out local cooling before the first pass of full longitudinal rolling, transporting the rolled piece to the position below a water flow device arranged in the middle of a roller way before the full longitudinal rolling, enabling the head and the tail of the rolled piece to correspond to cooling water pipes of the water flow device, starting cooling water, and cooling the internal temperature of the head and the tail of the rolled piece.

And the cooling area in the middle of the head and the tail of the rolled piece is 80-300 mm.

And the cooling time of the middle part of the head and the tail of the rolled piece is 30-240 s.

And after the temperature of the middle part of the head and the tail of the rolled piece is reduced by 30-200 ℃, the rolled piece is removed.

According to the method for controlling the head and tail shapes of the narrow-specification steel plate through the local temperature difference, the local cooling (surface temperature reduction of about 30-200 ℃) of the middle part in the head and tail width direction of a rolled piece (steel plate) with the width of less than or equal to 2200mm, the broadening ratio of less than or equal to 1.2 and the extension ratio of more than or equal to 10 can be realized through a rolling mill descaling system and/or a simple local cooling header, the deformation resistance of a temperature reduction area is increased before full longitudinal rolling at the implementation moment, the flow of the volume of the middle part can be reduced in the longitudinal rolling process, and the length of a head and tail fillet (tongue) after rolling is reduced.

Drawings

FIG. 1 is a schematic representation of the deformation of a prior art rolled product during free rolling to form a head-to-tail fillet;

FIG. 2 is a schematic diagram of the distribution of the upper region of the rolled piece when the local cooling of the rolled piece is achieved in the descaling mode of the method of the present invention;

FIG. 3 is a schematic diagram showing the distribution of the upper region of a rolled piece during the local cooling of a single tube water flow in the middle of a roller way in the method of the invention;

FIG. 4 is a schematic diagram of the principle of utilizing a rack descaling system to achieve local temperature difference of rolled pieces in the method of the present invention;

FIG. 5 is a schematic illustration of the method of the present invention utilizing a water flow means to achieve a localized temperature differential of the product (at 90 degrees rotation);

FIG. 6 is a logic diagram of the rack descaling system of FIG. 4 for achieving local temperature differentials across the rolled product;

FIG. 7 is a logic diagram of FIG. 5 for achieving local temperature differentials across the product using the water flow means.

Detailed Description

The technical scheme of the invention is further explained by combining the drawings and the embodiment.

Referring to fig. 2 to 7, the method for controlling the head and tail shapes of narrow-gauge steel plates through local temperature difference provided by the invention comprises a descaling mode for realizing local cooling of rolled pieces and local cooling of single-pipe water flow in the middle of a roller way;

preferably, the descaling mode realizes local cooling of the rolled piece, and comprises the following steps, please refer to fig. 4 first,

1) a frame descaling system 2 is arranged on the heavy and medium plate mill 1;

2) the full-length direction cooling is carried out on the middle part 3b of the width direction of the rolled piece 3 by utilizing the descaling water of the frame descaling system 2, and the method specifically comprises the following steps:

firstly, determining the pass of local cooling of a rolled piece 3, carrying out local cooling before the first pass of full longitudinal rolling, rotating the rolled piece 3 by 90 degrees (clockwise or anticlockwise) before the full longitudinal rolling is carried out, after parallel rolling in the width direction, transporting the rolled piece 3 to the position below a frame descaling system 2, enabling the rolled piece 3 to be in a static state, starting descaling water for cooling, dividing an edge area 3a, a middle area 3b and an edge area 3c on the rolled piece 3 in sequence according to the width direction of the rolled piece 3, moving out the rolled piece 3 after the temperature of the middle area 3b is reduced by 30-200 ℃, rotating by 90 degrees again, and carrying out longitudinal rolling with the head and the tail as the rolling direction.

Preferably, the descaling water cooling time is related to the thickness of the rolled piece 3 and is closed according to the plate thickness timing for 10-90 s.

Preferably, the partial cooling of the single-pipe water flow in the middle of the roller way comprises the following steps, please refer to fig. 5,

1) a water flow device 5 is arranged in the middle of a roller table 4 of the heavy and medium plate mill;

2) utilize rivers device 5's cooling water, cool off 3 head and the tail width direction middle parts of rolled piece, specifically do:

firstly, determining the pass of local cooling of a rolled piece 3, carrying out local cooling before the first pass of full longitudinal rolling, before the full longitudinal rolling, transporting the rolled piece 3 to the middle part of a roller way 4 below a water flow device 5, enabling the head and the tail of the rolled piece 3 to correspond to cooling water pipes of the water flow device 5, starting cooling water, and cooling the

middle parts

3d and 3e of the head and the tail of the rolled piece 3.

Preferably, the cooling area of the head and

tail middle parts

3d and 3e of the rolled piece 3 is 80-300 mm, which mainly refers to the length direction, that is, the length distance extending from the side edge to the middle part of the head and

tail middle parts

3d and 3e of the rolled piece 3, as shown in reference L in fig. 3.

Preferably, the cooling time of the head and tail

middle parts

3d and 3e of the rolled piece 3 is 30-240 s, and the specific cooling time is set according to the plate thickness and the temperature calculation.

Preferably, the rolled piece is removed after the temperature of the

middle parts

3d and 3e at the head and tail parts of the rolled piece 3 is reduced by 30-200 ℃.

The method changes the temperature distribution of the rolled piece through the water system, realizes different extensions by changing the deformation resistance of the local matrix of the rolled piece, and improves the plane shape. According to the temperature deformation resistance curve of the steel, the deformation resistance of the steel is small when the temperature is high, the deformation resistance of the steel is large when the temperature is low, and the deformation resistance of the area can be changed by reducing the local temperature to influence the volume flow. The temperature of the middle part of the rolled piece in the head and tail width direction is reduced before the rolled piece is longitudinally rolled (see the

areas

3d and 3e in fig. 3), and the temperature of the middle part of the rolled piece in the whole width direction can also be reduced (see the area 3b in fig. 2), the length direction of the rolled piece 3 in fig. 2 is the rolling direction, the upper middle area 3b of the rolled piece 3 in fig. 2 is a main temperature reduction area, and the surface temperature is reduced by 30-200 ℃ compared with the surface temperature of the two

edge areas

3a and 3 c. In the figure 3, the

middle parts

3d and 3e of the head and the tail of the rolled piece 3 are main temperature reduction areas, and the surface temperature is reduced by 30-200 ℃ compared with the surface temperature of the rest areas. The specific temperature value is determined by the specification of the rolled piece and the temperature of the rolled piece at the time, and the principle is that the narrower the width of the rolled piece, the larger the temperature drop is expected, the thicker the rolled piece, and the larger the temperature drop is expected. The deformation resistance of the low-temperature region is increased during rolling, the extension amount is reduced, the protruding area of the head and the tail of a rolled piece is reduced, the metal flow of the edge part is similar to the metal flow of the middle part, and the purpose of improving the head and tail shapes is achieved.

The method has the advantages that the cooling mode of the rolled piece is water system cooling, the efficiency is high, and the method is easy to realize. Particularly, modern medium and heavy plate rolling mills are provided with a frame descaling system, the pressure of the frame descaling system is high, moving rolled pieces are descaled in normal use, and if the frame descaling system is used for statically spraying a local area, the area cooling is very obvious. The medium plate rolling mill is provided with a steel rotating roller way, can realize the turning of a rolled piece, can be matched with a transport roller way, turns the rolled piece to be conveyed to the position below a descaling device in parallel with a descaling water system, and the descaling water can cool the middle part of the rolled piece in the width direction in the full length direction.

In addition, a simple water flow device is arranged in the middle of the roller way close to the rolling mill to cool the middle of the head and tail width directions of the rolled piece. The method can be used in hot rolling and medium plate production lines.

Example 1

Rolled stock slab size 250 x 1900 x 3061mm, rolled target size 16 x 2200 x 38300 mm. Rolling one block by a conventional method, and measuring head fillets by about 730mm (close tails) after rolling;

and the second block adopts a frame to descale to realize local temperature difference rolling. The thickness of the steel sheet before full longitudinal rolling was 195mm, and at this time, the steel sheet length was 3263mm, the width was 2189mm, and the steel sheet temperature was about 1100 ℃. Firstly, the head and tail directions of the steel plate are vertical to the rolling direction, the roll gap is opened to 235mm, the steel plate runs to the position below the descaling surface of the rolling mill (the middle part of the steel plate is similar to the position under the descaling surface), the descaling opening time is 50s, the steel plate is closed (the calculated temperature is reduced by 60 ℃), and the steel plate is rotated to the head and tail directions to be the same as the rolling direction. The fillet length of the head part is 470mm (the tail part is close) after rolling, and the implementation effect is obvious.

Example 2

The rolled piece slab size is 300 × 1500 × 3165mm, and the rolling target size is 18 × 1700 × 44000 mm. Rolling one block by a conventional method, and measuring the head fillet by about 880mm (the tail part is close) after rolling;

and the second block adopts a frame to descale to realize local temperature difference rolling. The thickness of the steel sheet before full longitudinal rolling was 251mm, and the steel sheet had a length of 3331mm, a width of 1704mm, and a temperature of about 1120 ℃. Firstly, the head and tail directions of the steel plate are vertical to the rolling direction, the roll gap is opened to 296mm, the steel plate runs to the position below the descaling of a rolling mill (the middle part of the steel plate is similar to the position under the descaling), the descaling is opened for 70s and closed (the calculated temperature is reduced by 80 ℃), and the steel plate rotates to the head and tail directions and is the same as the rolling direction. The head fillet length is 560mm (the tail is close) after rolling, and the implementation effect is obvious.

Example 3

Rolled piece slab size 180 x 1300 x 2680mm, rolled target size 12 x 1320 x 38000 mm. Rolling one block by a conventional method, and measuring head fillets by about 920mm (tail parts are close) after rolling;

and the second block adopts a frame to descale to realize local temperature difference rolling. The thickness before full longitudinal rolling was confirmed to be 180mm, the steel sheet length was 2680mm and width was 1300mm at this time, and the steel sheet temperature was about 1150 ℃. Firstly, the head and tail directions of the steel plate are vertical to the rolling direction, the roll gap is opened to 230mm, the steel plate runs to the position below the descaling surface of the rolling mill (the middle part of the steel plate is similar to the position under the descaling surface), the descaling opening is closed for 40s (the calculated temperature is reduced by 80 ℃), and the steel plate rotates to the head and tail directions and is the same as the rolling direction. The fillet length of the head part after rolling is 630mm (the tail part is close), and the implementation effect is obvious.

It should be understood by those skilled in the art that the above embodiments are only for illustrating the present invention and are not to be used as a limitation of the present invention, and that changes and modifications to the above described embodiments are within the scope of the claims of the present invention as long as they are within the spirit and scope of the present invention.

Claims

1. A method for controlling the head and tail shapes of narrow-specification steel plates through local temperature difference is characterized by comprising the following steps: the method comprises the steps of realizing local cooling of rolled pieces in a descaling mode and local cooling of single-pipe water flow in the middle of a roller way;

1) a frame descaling system is arranged on the heavy and medium plate mill;

2. The method for controlling the head-tail shape of the narrow-specification steel plate through the local temperature difference as claimed in claim 1, wherein the method comprises the following steps: step 2) of realizing local cooling of the rolled piece in the descaling mode specifically comprises the following steps:

3. The method for controlling the head-tail shape of the narrow-specification steel plate through the local temperature difference as claimed in claim 2, wherein the method comprises the following steps: and the descaling water cooling time is 10-90 s.

4. The method for controlling the head-tail shape of the narrow-specification steel plate through the local temperature difference as claimed in claim 2, wherein the method comprises the following steps: the rolled piece upper area is divided into: and dividing an edge region, a middle region and an edge region in sequence according to the width direction of the rolled piece.

5. The method for controlling the head-tail shape of the narrow-specification steel plate through the local temperature difference as claimed in claim 4, wherein the method comprises the following steps: and after the temperature of the upper middle area of the rolled piece is reduced by 30-200 ℃, moving out the rolled piece.

6. The method for controlling the head-tail shape of the narrow-specification steel plate through the local temperature difference as claimed in claim 1, wherein the method comprises the following steps: step 2) of locally cooling the single pipe water flow in the middle of the roller way specifically comprises the following steps:

7. The method for controlling the head-tail shape of the narrow-specification steel plate through the local temperature difference as claimed in claim 6, wherein the method comprises the following steps: and the cooling area in the middle of the head and the tail of the rolled piece is 80-300 mm.

8. The method for controlling the head-tail shape of the narrow-specification steel plate through the local temperature difference as claimed in claim 6, wherein the method comprises the following steps: and the cooling time of the middle part of the head and the tail of the rolled piece is 30-240 s.

9. The method for controlling the head-tail shape of the narrow-specification steel plate through the local temperature difference as claimed in claim 6, wherein the method comprises the following steps: and after the temperature of the middle part of the head and the tail of the rolled piece is reduced by 30-200 ℃, the rolled piece is removed.