KR101546243B1 - Control system and method for controlling the flow of second coolingwater in continuous casting processing - Google Patents

Abstract

A secondary cooling water quantity control system is introduced to extend the range of controllable cooling water.
To this end, the present invention comprises a main pipe provided with a main valve capable of controlling a certain amount of cooling water; An auxiliary pipe branching at one point of the main pipe; And a control unit for bypassing a part of the cooling water through the auxiliary pipe so that a range of controllable cooling water is widened by comparing a minimum flow rate value of the cooling water set in the main valve with a target flow rate value to be injected toward the steel strip. .

Description

TECHNICAL FIELD [0001] The present invention relates to a control system for a secondary cooling water quantity,

The present invention relates to a secondary cooling water quantity control system and a control method thereof, and more particularly, to a secondary cooling water quantity control system and a control method therefor, The present invention relates to a system for controlling a secondary cooling water quantity in a continuous casting machine capable of casting a wide range of peripheral speeds and various types of steel to which cooling and steel cooling are applied at the same time, and a method for using and controlling the system.

Generally, a general casting machine, that is, a continuous casting machine, is a machine in which a cast steel is continuously produced by lowering the molten steel stored in the ladle through a tundish and a mold, and the produced cast steel has to be adequately cooled at a considerably high temperature, The performance is performed by the secondary cooling system. In the secondary cooling system, the cooling water pumped from the pump is injected directly to the surface of the casting by each flow control loop through the flow control on the pipe, thereby forcibly cooling the casting, as shown in FIG.

FIG. 1 is a schematic view of a general performance secondary cooling system, and FIG. 2 is an enlarged view of the slab drive roll of FIG.

1 and 2, a general performance secondary cooling system is a system in which a programmable logic controller 2 provided with a flow rate setting value and a casting speed from an upper level controller 1 is connected to a casting 12 This is because the cooling water flowing through the cooling water pipe flows through the spray nozzle 8 and the slip between the driving rolls 11 in the segment 12 for drawing and supporting the slab 12, So that the casting 12 is cooled and the casting solidification is completed before the last segment 10.

At this time, the programmable logic controller 2 controls the opening and closing of the cooling water main pipe through the motor operation shutoff valve 5, and opens the cooling water main pipe by the motor operation cutoff valve 5 during the cooling water control, The flow rate control valve 3 of the branch pipe is controlled based on the flow rate detection value of the electromagnetic flowmeter 4 installed in each branch pipe extending from each flow control loop.

However, in the above-described secondary cooling system, since the flow rate is adjusted only by throttling of the flow control valve, the front end pressure of the flow control valve 3 is maintained at a predetermined pressure or higher, and the control range is limited.

In other words, when a conventional flow control valve is used in a performance operation, a certain range of cooling water quantity is controlled by the flow control valve. The minimum flow volume value and the maximum flow volume value among the range of controllable cooling water volume are set , The conventional flow control valve does not exceed approximately '10' due to the reason that the ratio of the minimum flow rate value and the maximum flow rate value is controlled only by the limit of the flow control valve device itself and throttling.

However, in general, continuous cooling requires both cooling and cooling of the cast steel at the same time depending on the casting speed and the type of steel. In the case of conventional flow control valves, the ratio of the minimum flow rate to the maximum flow rate does not exceed 10 It has been difficult to realize the simultaneous cooling and cooling of the cast steel by the same casting machine.

Accordingly, the present invention can increase the ratio between the minimum flow rate value and the maximum flow rate value to more than '10', and simultaneously apply the weak cooling and the strong cooling of the cast steel to the same casting machine simultaneously, The present invention relates to a castable system and a method thereof.

This enables casting over a wide range of castings and casting of a wide variety of steel grades that are very sensitive to cooling water.

As a related invention, Korean Patent Registration No. 10-0528503 entitled " Control Method of Secondary Cooling Water Flow Rate "and Korean Patent Laid-Open No. 10-2013-0075883 entitled" Cast Steel Temperature Control Apparatus and Method "

However, in the case of the above-mentioned " casting temperature control apparatus and method ", even if the amount of heat released from the mold changes, the temperature of the cast steel is kept constant, As a result, there is no technical idea to broaden the controllable range of cooling water jetted toward the cast steel by bypassing a part of the cooling water as in the present invention.

It should be understood that the foregoing description of the background art is merely for the purpose of promoting an understanding of the background of the present invention and is not to be construed as adhering to the prior art already known to those skilled in the art.

Korean Patent Registration No. 10-0528503 (November 7, 2005) Korean Patent Laid-Open Publication No. 10-2013-0075883 (July 31, 2013)

The present invention has been made in order to solve such conventional problems, and it is an object of the present invention to provide an auxiliary pipe for branching at one point of a main pipe for injecting cooling water toward a steel strip and a control unit for determining whether to bypass a part of the cooling water through the auxiliary pipe The present invention relates to a secondary cooling water quantity control system and a control method of the secondary cooling water system capable of casting not only a wide range of peripheral speed but also a variety of steel types by expanding the controllability range of cooling water .

A secondary cooling water quantity control system is introduced to extend the range of controllable cooling water.

To this end, the present invention comprises a main pipe provided with a main valve capable of controlling a certain amount of cooling water; An auxiliary pipe branching at one point of the main pipe; And a control unit for bypassing a part of the cooling water through the auxiliary pipe so that a range of controllable cooling water is widened by comparing a minimum flow rate value of the cooling water set in the main valve with a target flow rate value to be injected toward the steel strip. .

A sub valve for controlling the cooling water is provided at one point of the auxiliary piping, and when the control unit determines that the target flow rate value is smaller than the minimum flow rate value, the control unit transmits an open signal to the sub- And a part of the cooling water is bypassed.

On the other hand, a flow meter for detecting the cooling water quantity is installed at the tip of the nozzle through which the cooling water is injected toward the slab, and the controller compares the cooling water quantity sensed by the flow meter with the target flow quantity value in real time, And transmits a shutoff signal to the sub valve when the target flow rate value is reached.

Wherein an auxiliary flow meter for sensing cooling water is installed at one point of the auxiliary piping and the control unit controls the flow rate of the cooling water detected by the auxiliary flow meter to reach a flow rate corresponding to the difference between the minimum flow rate value and the target flow rate value The shutoff signal is transmitted to the sub-valve.

A second cooling water quantity control method of the performance device having the above-described configuration is introduced.

To this end, according to the present invention, a target flow rate value of cooling water injected toward the cast steel is set; Comparing the minimum flow rate value with the target flow rate value among a range of the adjustable cooling flow rate set in the main valve; Setting the cooling water flowable in the main valve to a minimum flow rate value when the target flow rate value is smaller than the minimum flow rate value; And bypassing a portion of the cooling water to the auxiliary piping so that the cooling water jetted toward the casting reaches the target flow rate value; .

At this time, an open signal is transmitted to the sub-valve provided in the auxiliary pipe to bypass a part of the cooling water.

Comparing the cooling water value of the flowmeter installed at the tip of the nozzle to which the cooling water is injected toward the target and the target flow rate value in real time after bypassing a part of the cooling water with the auxiliary pipe; And transmitting a shutoff signal to the sub valve when the cooling water value reaches the target flow rate value. Further comprising:

A part of the cooling water is bypassed to the auxiliary pipe and it is detected whether the cooling water value of the subsidiary flow meter provided at one side of the sub valve reaches the flow rate corresponding to the difference between the minimum flow value and the target flow rate value A step of transmitting a shutoff signal to the sub valve at the time of arrival; Further comprising:

According to the second cooling water quantity control system and the control method of the present invention having the above-described structure or process, the following various effects are realized.

First, when the present invention is used for secondary cooling quantity control during continuous casting, there is an advantage that a very wide range of cooling water quantity control can be obtained.

Second, the control range of cooling water is extended, which makes it possible to cast a wide range of castings and cast various steel grades that are very sensitive to cooling water.

Third, there are various advantages such that the cooling of the casting and the cooling of the casting can be simultaneously applied to the same casting machine.

1 is a configuration diagram of a general performance secondary cooling system;
Fig. 2 is an enlarged view of the slab drive roll of Fig. 1; Fig.
3 is a general configuration view of a second cooling water quantity control system of the present invention.
4 is a graph showing that the range of cooling water that can be controlled by applying the second cooling water quantity control system of the present invention is expanded.
5 is a flowchart of a second cooling water quantity control method of the present invention.
Figs. 6 and 7 are flowcharts showing that necessary cooling water is bypassed through an auxiliary valve so that cooling water corresponding to a target flow rate value is injected toward the casting. Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a control system and a control method thereof will be described with reference to the accompanying drawings.

3 is an overall configuration diagram of a secondary cooling water quantity control system of the present invention in which a main pipe 100, an auxiliary pipe 200, and a control unit 300 are installed.

Although not shown in the drawing, the main pipe 100 is connected to a pump for supplying cooling water, and cooling water injected toward the steel strip flows. A main valve 110 is installed at one point of the main pipe 100.

The main valve 110 is connected to the first flow meter 120 installed on one side of the main valve 110 and has a predetermined range of the amount of cooling water jetted toward the casting. A spray nozzle 400 connected to one end of the main pipe 100 The cooling water is injected through the cooling water passage.

Although the range of the cooling water quantity has already been described, the ratio of the minimum flow quantity value to the maximum flow quantity value, which is the control range of the cooling water quantity, is approximately '10 There is a problem that can not exceed '.

An auxiliary piping 200 is provided at one point of the main valve 110 to bypass a portion of the cooling water flowing through the main valve 110 by a control unit 300 to be described later.

By bypassing a part of the cooling water through the auxiliary pipe 200 when the cooling water to be sprayed toward the steel strip is smaller than the minimum flow rate of the cooling water amount set in the main valve 110 and adjustable, It is possible to broaden the range of the cooling water that can be adjusted by the heat exchanger 110.

Meanwhile, the controller 300 is provided around the main pipe 100 and the auxiliary pipe 200 to enable such adjustment.

The control unit 300 compares the minimum flow rate among the cooling water within a predetermined range set in the main valve 110 and the target flow rate value to be sprayed toward the cast steel, And performs a bypass function.

For example, when the range of the cooling water that can be controlled by the main valve 110 provided in the main pipe 100 is 40 to 400 (L / min) and the target to which the cooling water is sprayed from the spray nozzle 400 Assuming that the flow rate value is 10 (L / min), there is a problem that the cooling water value toward the slab can not be controlled through the main valve 110.

Therefore, when the present invention is not installed in the field, the ratio of the minimum flow rate value and the maximum flow rate value that can be injected toward the slab through the main valve 110 is approximately '4'.

In this case, the control unit 300, which is a component of the present invention, has already set a 'target flow rate value' to be sprayed toward the billet, and the 'target flow rate value' And then bypasses some of the cooling water flowing through the main pipe 100 so that only the 'target flow rate' is sprayed from the spray nozzle 400 toward the target.

That is, a sub-valve 210 is provided at one point of the auxiliary pipe 200 to adjust the range of the cooling water that can flow through the auxiliary pipe 200. The control unit 300 determines whether the target flow rate The control unit 100 transmits an open signal to the sub-valve 210 to bypass a portion of the cooling water flowing along the main pipe 100.

For example, when the range of the cooling water that can be controlled by the main valve 110 installed in the main pipe 100 is 40 to 400 (L / min) and the cooling water is sprayed toward the slip through the spray nozzle 400 Assuming that the target flow rate value is 10 (L / min), the control unit 300 determines that the minimum flow rate value is 40 (L / min) and the target flow rate value is 10 An open signal is transmitted so that 30 (L / min) of cooling water flows through the auxiliary pipe 200 to control the amount of cooling water injected toward the steel strip to be 10 (L / min).

On the other hand, as shown in Fig. 3, when the cooling water is injected to the casting material by bypassing part of the cooling water through the auxiliary pipe 200 and determining whether or not the cooling water injected toward the casting material reaches the target flow rate value And a flow meter 500 for sensing the cooling water quantity at the tip of the nozzle (spray nozzle).

The control unit 300 compares the cooling water detected by the flow meter 500 and the target flow rate in real time, and when the cooling water detected by the flow meter 500 reaches the target flow rate value, A blocking signal is transmitted.

That is, the range of the cooling water that can be controlled by the main valve 110 installed in the main pipe 100 is 40 to 400 (L / min), and the target flow rate at which the cooling water is sprayed toward the steel strip through the spray nozzle 400 (L / min), the control unit 300 determines that the open valve is open to the sub valve 210 because the minimum flow rate is 40 (L / min) and the target flow rate is 10 (L / min) The control unit 300 continuously controls the amount of cooling water detected by the flow meter 500 installed at the tip of the nozzle 400 to 10 L / min, the shutoff signal is transmitted to the sub-valve 210 installed at one point of the auxiliary piping 200 again.

3, in order to extend the range of the cooling water that can be controlled by the main valve 110 installed in the main pipe 100, the auxiliary pipe (not shown) 200 is provided with an auxiliary flow meter 220 for sensing the amount of cooling water flowing through the auxiliary pipe 200 at one point.

At this time, the control unit 300 transmits a shutoff signal to the sub valve 210 when the cooling water sensed by the auxiliary flow meter 220 reaches the flow rate corresponding to the difference between the minimum flow rate value and the target flow rate value .

That is, the range of the cooling water that can be controlled by the main valve 110 installed in the main pipe 100 is 40 to 400 (L / min), and the target flow rate at which the cooling water is sprayed toward the steel strip through the spray nozzle 400 Assuming a value of 10 (L / min), the cooling water sensed by the auxiliary flow meter 220 corresponds to the difference between the minimum flow rate of 40 (L / min) and the target flow rate of 10 (L / min) A shutoff signal is sent to the sub valve 210 to adjust the target flow rate to be 10 (L / min) as the target flow rate through the spray nozzle 400.

FIG. 4 is a graph illustrating the relationship between the minimum flow rate and the maximum flow rate of the present invention. Referring to FIG.

As shown in the drawing, the minimum flow rate and the maximum flow rate of the cooling water controlled by the present invention are 0.6 (L / min) and 25 (L / min) at the pressure range of 0.05 to 8 bar, '.

On the other hand, a method of controlling the secondary cooling water quantity of the performance equipment with the above-described configuration is introduced.

As shown in FIG. 5, a process (S10) of setting a target flow rate value of the cooling water jetted toward the steel strip is performed first.

At this time, the amount of cooling water to be injected is set to be low so that the cooling of the cast steel can be performed, or the cooling water to be injected is set to be high so that steel cooling can be performed.

The target flow rate value is stored in the control section described above, and is compared with a minimum flow rate value described later.

Thereafter, a process S20 is performed to compare the minimum flow rate and the target flow rate among the ranges of the adjustable cooling water set in the main valve. When the target flow rate value is smaller than the minimum flow rate value in the comparison, (S30) is set to the minimum flow rate value which is the smallest among the range of the cooling water flow that can be set and flowed.

For example, if the target flow rate value to be sprayed toward the slab is 10 (L / min) and the range of the cooling water quantity that can be controlled by the main valve is 40 to 400 (L / min) (L / min), which is the minimum flow rate value. In this case, the control unit previously described transmits a signal to the main valve that fixes the cooling water flowable through the main valve at 40 (L / min).

Thereafter, a portion of the cooling water is bypassed to the auxiliary pipe (S40) so that the cooling water jetted toward the steel strip reaches the target flow rate value. In this example, 40 (L / min) (L / min) flows through the auxiliary piping.

An open signal is transmitted to the sub valve 210 provided in the auxiliary pipe 200 so that a part of the cooling water can flow through the auxiliary pipe 200 to bypass some of the cooling water.

Meanwhile, as shown in FIG. 6, during the process of bypassing a part of the cooling water through the auxiliary pipe, when the amount of cooling water injected toward the pipe reaches the target flow rate value, The following are specific steps to prevent the flow of water.

A step S50 of comparing the cooling water quantity value of the flow meter 500 provided at the tip of the nozzle 400 to which the cooling water is injected toward the target with the target flow rate value after bypassing a part of the cooling water with the auxiliary pipe 200 ). This comparison process can be performed in the control unit already described.

As a result of the comparison, when the cooling water value reaches the target flow rate value, the control unit transmits a shutoff signal to the sub valve 210 so that the cooling water is no longer bypassed through the auxiliary pipe (S60).

As shown in FIG. 7, the operation for preventing the cooling water from flowing through the auxiliary pipe 200 when the target flow rate value is injected into the strip as described above may be performed as follows.

A part of the cooling water is bypassed to the auxiliary piping and then a check is made to determine whether the cooling water value of the auxiliary flow meter 220 installed at one side of the sub valve 210 reaches the flow rate corresponding to the difference between the minimum flow rate value and the target flow rate value (S70) of transmitting a shutoff signal to the sub valve (210) upon reaching the detection result.

While the present invention has been particularly shown and described with reference to specific embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the following claims It will be apparent to those of ordinary skill in the art.

100: main pipe 110: main valve
200: auxiliary piping 210: sub-valve
220: auxiliary flow meter 300:
400: Nozzle 500: Flowmeter

Claims (8)

A main pipe provided with a main valve capable of controlling a certain amount of cooling water;
An auxiliary pipe branching at one point of the main pipe;
A sub-valve installed in the auxiliary pipe to control the amount of cooling water passing through the auxiliary pipe;
An auxiliary flow meter installed on the auxiliary pipe to sense the amount of cooling water discharged through the auxiliary pipe; And
When the target flow rate value is smaller than the minimum flow rate value so as to increase the range of the controllable cooling rate after comparing the minimum flow rate value of the cooling water set to the main valve with the target flow rate value to be sprayed toward the steel strip, An open signal is transmitted to the sub-valve to bypass a portion of the cooling water flowing along the main pipe, and when the cooling water sensed by the auxiliary flow meter reaches a flow rate corresponding to the difference between the minimum flow rate value and the target flow rate value A control unit for transmitting a shutoff signal to the sub valve; And a second cooling water quantity control system.
delete The method according to claim 1,
A flow meter for detecting the cooling water is provided at the tip of the nozzle provided at one end of the main pipe so as to inject cooling water toward the cast steel,
Wherein the control unit compares the cooling water detected by the flow meter with the target flow rate value in real time and transmits a shutoff signal to the sub valve when the cooling water reaches the target flow rate value, Cooling water quantity control system.
delete Setting a target flow rate value of the cooling water injected toward the casting;
Comparing the minimum flow rate value with the target flow rate value among a range of the adjustable cooling flow rate set in the main valve;
Setting the cooling water flowable in the main valve to a minimum flow rate value when the target flow rate value is smaller than the minimum flow rate value;
Transmitting an open signal to a sub-valve provided in an auxiliary pipe to bypass a portion of the cooling water with the auxiliary pipe so that the cooling water jetted toward the steel strip reaches the target flow rate value;
Comparing the cooling water quantity value of the flow meter provided at the tip of the nozzle provided at one end of the main pipe with the target flow quantity value in real time so as to inject cooling water toward the product; And
And transmitting a shutoff signal to the sub valve when the cooling water value reaches the target flow rate value.
delete delete The method of claim 5,
After a part of the cooling water is bypassed to the auxiliary pipe,
Detecting whether a cooling water quantity of an auxiliary flow meter provided at one side of the sub valve reaches a flow rate corresponding to a difference between the minimum flow value and the target flow rate value and transmitting a shutoff signal to the sub valve at the time of arrival ; Further comprising the step of controlling the second cooling water quantity.

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