KR101159905B1 - Cooling method for inverted angle - Google Patents

Abstract

The method for cooling the trapezoidal angle after the trapezoid of the present invention is a position in the cooling system of both ends of the trapezoidal angle after the trapezoid when the rolled trapezoid is rolled to have a short side and a long side which are different in length and thickness from each other. Sensing and outputting the signal as an electrical signal, based on a position in the cooling equipment at both ends of the trapezoidal angle, which is recognized from the electrical signal, at least a portion of both ends of the trapezoidal angle after the trapezoid is controlled by the cooling system Determining whether the section overlaps with each other and if at least a portion of both ends of the post trapezoid angle overlap with a predetermined control section of the cooling system, supplying the post trapezoid to the post trapping angle from the predetermined control section of the cooling system. Outputting a control signal for controlling the operation of said cooling installation to differentially supply cooling water. The.

Accordingly, the present invention has a useful effect of suppressing the occurrence of warp at both ends of the angle after the trapezoid is improved, thereby improving the product recovery rate.

Equilateral sides after inequality angle, long side, short side

Description

Cooling method for inverted angle

The present invention relates to a method for cooling an isosceles angle after an isosceles angle, and more particularly, a method for cooling an isosceles angle after an isosceles angle, which can reduce the variation of the cooling temperature of both ends and the center of an isosceles angle. It is about.

In general, the inverted angle is an inverted angle that is used for the welding structure of decks and main parts of large ships. It is suitable for the hull structure because of its good weldability. In addition, it is used as a ship member to disperse or minimize impact during operation.

Conventional trapezoidal angles after an inequality are formed in the shape of "￢" having a long side and a short side, and have different lengths and thicknesses of the sides.

After the trapezoidal angle, the angle is formed in an angle shape while being heated through a heating furnace and passed through a rolling mill having a plurality of rolling rollers, which is then cooled and cooled on a cooling bed, and then cut into lengths desired by the user. Have

However, in the conventional trapezoidal angle after inequality, even if the same amount of cooling water is uniformly supplied due to the different lengths and thicknesses of the long side and the short side, the deformation occurs due to the difference in the cooling rates of the long side portions. In particular, in the case of a product longer than 20m, the amount of deformation becomes more severe.

In the case of a product that is excessively deformed such a warpage, the insertion of the braces is impossible, and even if the insertion of the braces is possible, a product defect in which a wavy pattern is formed is caused.

In other words, the angle of inequality after inequality is deformed due to the different characteristics of the length and thickness of the long side and the short side, which have different cooling speeds during atmospheric cooling after entering the cooling phase, especially in the case of long products longer than 20m Since the cooling rate is cooled faster than the central part, the physical properties of both ends are lowered, so that a part (1.0-2.5m) of both ends is cut and the cut part is discarded.

Accordingly, there is a problem that the product recovery rate is lowered and the productivity is lowered, and in the case of a large product having a long length, an excessive amount of warpage occurs and there is a problem in manufacturing.

The present invention has been proposed to solve the above problems in view of the above problems, the object of the trapezoidal angle after the trapezoid of the trapezoidal angle that can reduce the cooling temperature deviation of the both ends and the central portion of the angle after the trapezoid having a long side and a short side of different length To provide a cooling method.

The method for cooling the trapezoidal angle after the trapezoid of the present invention for achieving the above object, when the trapezoidal angle after the trapezoid is rolled to have a short side and a long side different in length and thickness from each other, passing through the cooling facility, Detecting a position in the cooling equipment at both ends and outputting it as an electrical signal; based on the position in the cooling equipment at both ends of the trapezoidal angle, which is recognized from the electrical signal, at least a portion of both ends of the trapezoidal angle Determining whether the control section overlaps with a predetermined control section of the cooling system, and if at least a portion of both ends of the trapezoidal angle is overlapped with a predetermined control section of the cooling system, the control section of the cooling system includes: To control the operation of the cooling system to differentially supply the cooling water supplied to the angle after the inequality. Outputting the fish signal.

The control signal may be a control signal for stopping supply of the cooling water supplied to both ends of the angle after the inequality.

In addition, the control section of the cooling facility may be any one section of the entry section or the discharge section of the cooling facility.

In addition, the entrance section of the cooling facility may be within a range of 4m from one end of the cooling facility.

In addition, the discharge section of the cooling facility may be within a range of 4m from the other end of the cooling facility.

The present invention differentially supplies the supply of cooling water injected at both ends and the central portion of the trapezoid angle after the trapezoid angle of the trapezoid angle after the trapezoid isotropic angle so that the cooling rate of each part of the angle after trapezoid is cooled equally It has a useful effect of suppressing the occurrence of warp at both ends of the post trapezoid angle, thereby improving the product recovery rate.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a graph showing the temperature distribution and the cooling rate before and after cooling of the angle after the trapezoid.

Referring to FIG. 1, in the case of an isosceles inequality angle of 67m in length, the temperature distribution before and after cooling is different due to the structural characteristics of the shape of the length and thickness of the long side and the short side are different, especially in the case of a long product longer than 20m The temperature difference before and after cooling is large, and as a result, as shown in FIG. 1A and B, it can be seen that the cooling speed of both ends is cooled faster than the center portion.

In this case, since the physical properties of both ends are lower than that of the central part, a portion (1.0-2.5 m) of both ends is cut and the cut part is discarded. Therefore, it is necessary to control so as to differentially supply the amount of cooling water injected at both ends compared to the central portion of the angle after the trapezoid.

Figure 2 is a configuration diagram showing the cooling water supply structure of the post trapezoid angle according to the present invention, Figure 3a, 3b, 3c is a case where the control section in the cooling method of the trapezoid angle after the trapezoid according to an embodiment of the present invention In this figure, the tip cooling process is shown in sequence.

After the base material, which is a steel semifinished product (for example, Bloom), is heated in a furnace and rolled to have a long side 12 and a short side 14 having different thicknesses and lengths, the rolled trapezoidal inequality angle 10 is shown in FIG. 1. After cooling rapidly by using a water-cooled cooling system as described above, the air is cooled on a cooling bed.

The rapid cooling section may be formed on the short side 14 and the long side 12 of the post trapezoidal angle 10 while transferring the post trapezoidal angle 10 to the inside of the cooling facility C as shown in FIG. 2A. It means a section in which cooling water is supplied and rapidly cooled.

The method for cooling the trapezoidal angle after the trapezoid of the present invention is an trapezoid when the trapezoidal edge 10 rolled to have a short side 14 and a long side 12 having different lengths and thicknesses from each other passes through the cooling facility C. And detecting the position (C) in the cooling facilities of both ends 10A and 10B of the angle 10 after the inequality, and outputting it as an electrical signal.

Specifically, at least one detection sensor (S) is disposed in a predetermined control section of the cooling facility (C) so that both ends of the trapezoidal angle (10) after the inequality angle 10 passes through the cooling facility (C). Detects the position in the cooling system (C) of (10A, 10B) and detects the entry and exit timing of the angle 10 after inequality and outputs it as an electrical signal. Here, the predetermined control section (D) means any one of the entry section or the discharge section of the cooling facility (C).

The entry section of the cooling installation (C) is a section corresponding to one end of the cooling installation (C) into which the angle 10 enters after the trapezoidal inequality, and preferably within 4 m from one end of the cooling installation (C). Correspondingly, the discharge section of the cooling installation (C) is a section corresponding to the other end of the cooling installation (C) from which the angle 10 after the trapezoidal inequality escapes, preferably within 4 m from the other end of the cooling installation (C). It is a range.

In addition, the both ends 10A and 10B of the trapezoid angle 10 after the inequality mean the front end 10A and the rear end 10B.

In this case, the entry section and the discharge section are 4m, respectively, because the area where the deformation of the leading end portion 10A or the rear end portion 10B of the trapezoidal inequality angle 10 occurs mainly is within 4m of both ends of the trapezoidal angle inequality 10. Because it is.

3A to 3C, the following description will be given only when the predetermined control section D is an entry section of the cooling facility C.

Referring to FIG. 3A, at least one detection sensor S is disposed in an entry section that is a predetermined control section D of the cooling facility C. Referring to FIG.

The detection sensor S is disposed at least one in the entry section (D) to detect the timing of entering the angle 10 after the trapezoidal inequality, or the feed rate of the trapezoid angle 10 after the trapezoid is fed along the roller table and set in advance The product information (length, thickness, etc.) can be calculated to recognize the front and rear ends.

For example, the process of detecting both ends (10A, 10B) of the angle 10 after the inequality inequality in the entry section (D) of the cooling facility (C) a plurality of detection sensors disposed spaced apart from each other in the entry section (D) By using S) it is possible to detect and recognize the front end and the rear end of the trapezoid angle (10) in transit. In addition, by using a plurality of detection sensors (S) disposed spaced apart from each other in the entry section (D) and in close proximity to the entry section (D) by detecting the leading end and the rear end of the angle 10 after inequality being transported It can also be recognized.

When an electrical signal is output by the detection sensor S disposed in the entry section D, the electrical signal regarding the position of the cooling equipment C of the both ends 10A and 10B of the angle 10 after the inequality is inverted, the controller (not shown) After receiving the electrical signal, and based on this it recognizes the position in the cooling system (C) of the both ends (10A, 10B) of the inequality side 10 after the inequality.

The controller determines whether at least a portion of both ends 10A and 10B of the trapezoidal angle 10 recognized from the electrical signal overlap with a predetermined control section of the cooling installation C.

As shown in FIGS. 3A and 3B, the positions of both ends 10A and 10B of the isosceles inequality angle 10 enter the predetermined control section, that is, the entrance section D of the cooling installation C, and both ends 10A. , Part 10B) overlaps with the entry section D, the cooling facility (C) to differentially supply the cooling water supplied to both ends (10A, 10B) of the angle 10 after the inequality side inequality in the entry section (D) Outputs a control signal to control the operation of.

In detail, as shown in FIGS. 3A and 3B, the controller is configured such that the front end portion 10A of the inequilateral inequality angle 10 recognized from the electrical signal enters the entry section D, and thus a part of the front end portion 10A. Alternatively, when all of them overlap with the entry section D, the operation of the coolant supply unit C _in the entry section D so as to differentially supply the coolant supplied from the entry section D to the angle 10 after inequality. Output a control signal to control.

Here, the control signal is a control signal for stopping the supply of the cooling water supplied to the angle 10 after the inequality side inequality in the entry section (D). That is, the controller outputs a control signal for turning off the supply of the cooling water supplied to the angle 10 after the inequality side inequality in the entry section D to the cooling water supply unit C _in located in the entry section.

Therefore, as shown in FIGS. 3A and 3B, since the supply of cooling water is turned off at the tip portion 10A of the trapezoidal angle 10 after the trapezoidal inequality, the coolant supplied to the tip portion and the central portion of the angle 10 after the trapezoid is anisotropy is turned off. The amount is different.

As shown in FIG. 3C, the tip portion 10A of the trapezoidal angle 10 passes completely through the entry section, so that at least a portion of both ends 10A and 10B of the trapezoidal angle 10 after the trapezoid is uncooled. When not overlapping with the entry section (D) of the), the coolant is supplied to the cooling water supply unit (C _in ) located in the entry section (ON) again.

Thereafter, the trapezoid angle 10 after passing through the cooling equipment (C), the trailing end 10B of the trapezoid angle 10 after entering the entry section (D), the trapezoid angle after the trapezoid angle (10) Similarly to the case where the distal end portion 10A of the angle 10 enters the entry section D even after part or all of the rear end portion 10B of the) overlaps with the entry section D, the control unit The control signal for stopping the supply of the cooling water supplied to the rear end portion 10B of the angle 10 after the inequality side inequality in the entry section D is output to the cooling water supply unit C _in located in the entry section D.

As described above, after the inequality side inequality by supplying the cooling water of the entrance section of the cooling facility C by the control signal output from the control unit differentially by the both ends 10A, 10B of the angle 10 and other parts. The cooling rates of the front end portion 10A and the rear end portion 10B of the angle 10 may coincide with the cooling rates of the central portion.

In FIG. 3A to FIG. 3C, the description has been made only in the case where the predetermined control section D is the entrance section of the cooling installation C. However, even when the predetermined control section D is the discharge section of the cooling installation C. FIG. The same can be applied.

Figures 4a, 4b is a configuration diagram sequentially showing the rear end cooling process when the control section is the discharge section in the cooling method of the trapezoid angle after the trapezoid according to another embodiment of the present invention.

4A and 4B, at least one detection sensor S is disposed in a discharge section that is a predetermined control section D of the cooling system C. Referring to FIGS. At least one detection sensor (S) is disposed in the discharge section (D) to detect the discharge timing of the angle 10 after the inequality and the inequality side in the same manner as the detection sensor (S) as described above disposed in the entry section After the inequality, the front end portion 10A and the rear end portion 10B of the angle 10 can be recognized.

When an electrical signal about the position in the cooling system C of the rear end portion 10B of the angle 10 after the inequality side is output by the detection sensor S disposed in the discharge section D, the controller (not shown) After receiving the electrical signal, it recognizes the position in the cooling facility (C) of the rear end (10B) of the angle 10 after the trapezoid on the basis of this.

The controller determines whether at least part of the rear end portion 10B of the trapezoidal angle 10 recognized from the electrical signal overlaps with a predetermined control section of the cooling installation C.

As shown in FIG. 4B, the control unit enters a predetermined control section, that is, a discharge section D of the cooling system C, after the position of the rear end portion 10B of the trapezoidal inequality angle 10 reaches the rear end portion 10B. If any part of the) overlaps with the discharge section (D), the operation of the cooling system (C) so as to differentially supply the cooling water supplied to the both ends (10A, 10B) of the angle 10 after the trapezoid inequality in the discharge section (D). Outputs a control signal to control.

In detail, as illustrated in FIG. 4B, the controller may include a rear end portion 10B of the inequilateral inequality angle 10 that is recognized from the electrical signal, and enters an entry section D so that a portion of the rear end portion 10B may be formed. If all of them overlap with the discharge section (D), the operation of the cooling water supply unit (C _out ) disposed in the discharge section (D) so as to differentially supply the cooling water supplied to the angle 10 after the trapezoid inequality in the discharge section (D). Outputs a control signal to control.

Here, the control signal is a control signal for stopping the supply of the cooling water supplied to the angle 10 after the inequality side inequality in the discharge section (D). That is, the controller outputs a control signal for turning off the supply of the cooling water supplied to the angle 10 after the inequality side inequality in the discharge section D to the cooling water supply unit C _out located in the discharge section.

Therefore, as shown in FIG. 4B, since the supply of cooling water is turned off at the rear end 10B of the post trapezoid angle 10, the cooling water supplied to the rear end and the central portion of the post trapezoid angle 10 is turned off. The amount is different.

In this way, by the control signal output from the control unit by supplying the cooling water of the discharge section of the cooling facility (C) by differentially supplying the rear end portion 10B of the angle 10 and other parts of the trapezoidal side after the trapezoid The cooling rate of the rear end 10B of (10) can be matched with the cooling rate of the central portion.

On the other hand, in the above described using the detection sensor S to detect the timing of entering the entry section (D) of the angle 10 after the trapezoidal inequality, product information of the angle 10 after the trapezoid is inevitably set, When the feed rate through the roller table is set in advance, the control unit calculates the feed rate and the product information, and the coolant supply unit C _in or C when the leading end portion and the rear end portion of the angle 10 after product pass through the control section, respectively. The cooling water supply can be stopped by blocking the cooling water supplied by the _out ).

As described above, the present invention is characterized in that the supply of the cooling water is differentially supplied by stopping the cooling water supply when both ends of the trapezoidal angle 10 pass through the control section of the cooling facility C.

That is, during the transfer of the cooling phase, there is a risk of warpage because the central portion of the angle 10 after the trapezoid is inferior to both ends, and to compensate for this, the supply of cooling water injected to both ends of the angle 10 after the trapezoid is unbalanced. By stopping the operation, warpage can be suppressed by reducing the difference in cooling rate for each part in the atmosphere during the transport of the cooling phase.

Because of this, even if the angle 10 after the trapezoidal inequality that passed through the cooling facility (C) occurs, this is only a warp within a range that can be sufficiently corrected through a straightener. After the trapezoidal inequality angle 10 which has passed through this cooling facility C is calibrated through a calibrator via a cooling phase, it is cut to the final product length in the cutter. Here, since the calibrator and the cutter adopt the conventionally known one, a detailed description thereof will not be mentioned.

Therefore, since more cooling water is supplied to the central portion than both ends during the cooling process of the angle 10 after the trapezoidal inequality, it is possible to reduce the temperature variation for each portion, thereby suppressing the occurrence of torsion or warpage.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

1 is a graph showing the temperature distribution and the cooling rate before and after cooling of the angle after the trapezoid,

Figure 2 is a block diagram showing the cooling water supply structure of the trapezoid angle after trapezoid according to the present invention,

Figure 3a, 3b, 3c is a configuration diagram sequentially showing the front end cooling process, when the control section is the entry section in the cooling method of the inequilateral angle after inequality according to an embodiment of the present invention,

Figures 4a, 4b is a configuration diagram sequentially showing the rear end cooling process when the control section is the discharge section in the cooling method of the trapezoid angle after the trapezoid according to another embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS Fig.

10: after inequilateral angle 10A: distal end

10B: rear end 12: long side

14: short side C: cooling system

C1, C2, C3: Cooling water supply part S: Sensor

C _in : Coolant supply _{in the} entry section

C _out : Cooling water supply in discharge section

Claims (5)

When the trapezoidal post-etched angle 10 rolled to have a short side and a long side having different lengths and thicknesses from each other passes through the cooling facility C, the position in the cooling installation C of both ends of the trapezoidal angle 10 after the trapezoid is changed. Sensing and outputting it as an electrical signal; At least a part of both ends of the trapezoidal angle 10 after the trapezoidal angle 10 is predetermined by the cooling unit C based on the position in the cooling unit C of the both ends of the trapezoidal angle 10 after being recognized from the electrical signal. Determining whether the control interval is overlapped with; And If at least a portion of both ends of the trapezoidal angle 10 after the trapezoid overlaps with a predetermined control section of the cooling facility C, the trapezoidal angle after the trapezoidal angle 10 in the predetermined control section of the cooling device C And outputting a control signal for controlling the operation of the cooling facility C to differentially supply the cooling water to be supplied thereto. The control section of the cooling facility (C) is the cooling method of the trapezoid angle after the trapezoid, characterized in that any one of the entry section or the discharge section of the cooling installation (C). The method according to claim 1, And the control signal is a control signal for stopping the supply of the cooling water supplied to both ends of the post trapezoid angle. delete The method according to claim 1, The inlet section of the cooling device (C) is the cooling method of the trapezoid angle after the trapezoid, characterized in that within 4m from one end of the cooling system. The method according to claim 1, The discharge section of the cooling system (C) is an angle trapping after the trapezoidal angle, characterized in that within 4m from the other end of the cooling system.

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