KR20120000796A - Apparatus for measuring temperature of turndish and system for monitering temperature of turndish - Google Patents

Abstract

PURPOSE: A turn dish temperature measuring device and a temperature monitoring system are provided to improve process stability by reducing noise due to damage to a cable. CONSTITUTION: A turn dish temperature measuring device comprises a temperature detection module(11), A/D converter(15), and a radio transmitter(16). The temperature detection module is installed in a wall of a tundish(3) and measures the temperature of the molten steel saved in the tundish. The temperature detection module comprises the temperature sensor. The temperature sensor is inserted in the wall of the tundish to be protected from molten metal by a protecting pipe. The A/D converter changes the temperature information, which is measured by the temperature detection module, into a digital signal. The radio transmitter transmits the signal to the controller(20).

Description

Applitus for measuring temperature of turndish and system for monitering temperature of turndish}

The present invention relates to a tundish molten steel temperature measuring apparatus that can more easily and safely measure the molten steel temperature of the tundish in a continuous casting facility.

In the steelmaking process, the continuous casting method has become the mainstream in the past, which has deviated from the conventional ingot method, which required the skill and advanced skill of the worker in the steelmaking process. It refers to a process of producing slabs as unit products by solidifying molten steel by cooling water spraying to ensure optimal quality.

Such continuous casting includes both the ingot and the ingot process by the conventional ingot method, and the process is omitted compared to the ingot method, thus achieving a product yield of 10% or more, increasing the productivity, improving the productivity and casting the slab. It has a great effect on improving the quality stability of) and is used in almost all kinds of steels including stainless steel except some special steels.

It is an object of the present invention to provide a tundish temperature measuring apparatus that can more easily and safely measure the molten steel temperature of a tundish in a continuous casting facility.

Tundish temperature measuring apparatus according to an aspect of the present invention is installed on the wall of the tundish and measuring the temperature of the molten steel stored in the tundish; An A / D converter converting the temperature measured by the temperature measuring module into a signal; And a wireless transmitter for transmitting the signal to the controller.

In this case, the temperature measurement module may include a temperature sensor inserted through the wall of the tundish and protected from the heat of the molten steel by a protective tube.

In addition, the temperature measurement module may include a plurality of temperature sensors inserted into the wall of the tundish and arranged to have a sequential height in the thickness depth direction of the wall of the tundish.

In addition, the A / D converter and the wireless transmitter are installed on an outer wall of the tundish.

Tundish temperature monitoring system according to another aspect of the present invention is a temperature measuring module for measuring the temperature of the molten steel stored in the tundish in contact with the wall of the tundish, converting the temperature information about the temperature measured by the temperature measuring module into a digital signal A temperature measuring device including an A / D converter for transmitting the digital signal to the control unit; A wireless receiver for receiving the transmitted signal; And a control unit for monitoring the temperature of the tundish using the data received from the wireless receiver.

On the other hand, the temperature measuring device is provided with a plurality of heights on the wall and floor of the tundish, the control unit calculates the temperature gradient inside the tundish by using the data received from the plurality of temperature measuring devices. It is done.

In this case, the temperature measurement module may include a temperature sensor inserted through the wall of the tundish and protected from the heat of the molten steel by a protective tube.

In addition, the temperature measurement module may include a plurality of temperature sensors inserted into the wall of the tundish and arranged to have a sequential height in the thickness depth direction of the wall of the tundish.

In addition, the A / D converter and the wireless transmitter are installed on an outer wall of the tundish.

By processing the data on the temperature by using the wireless transceiver, the device can be simplified, and the generation of noise due to cable damage can be reduced, so that the entire process can be performed stably, and the probe is not directly injected into the molten steel. It does not need to be replaced, which is advantageous in terms of cost.

1 is a schematic view showing a tundish temperature measuring apparatus and a continuous casting facility according to an aspect of the present invention.
Figure 2 is a block diagram showing an embodiment of a tundish temperature measuring apparatus according to an aspect of the present invention.
Figure 3 is a block diagram showing another embodiment of a tundish temperature measuring apparatus according to an aspect of the present invention.
Figure 4 is a block diagram showing an embodiment of a tundish temperature monitoring system according to another aspect of the present invention.
Figure 5 is a schematic diagram showing the position of the temperature measuring device in another embodiment of the tundish temperature monitoring system according to another aspect of the present invention.

Hereinafter, the detailed description will be described with reference to the accompanying drawings.

1 is a schematic view showing a tundish temperature measuring apparatus and a continuous casting facility according to an aspect of the present invention, ladle (1), molten steel (2), tundish (3), mold (4), roll (5), A sliding nozzle 6, a tundish temperature measuring device 10 is shown.

Ladle (1) is a tub containing the refined molten steel (2), a plurality of ladles (1) alternately for continuous casting to supply the molten steel (2) for making the slab.

The tundish 3 is buffered to supply the molten steel 2 from the ladle 1 temporarily to the mold 4 before the molten steel 2 flows into the mold 4 forming the slab shape. It is installed for the purpose of quality control by separating the role and floating of nonmetallic inclusions. The tundish 3 is surrounded by an iron plate and a fireproof wall to withstand flame.

When the sliding nozzle 6 in the lower portion of the tundish 3 is opened, the molten steel 2 is cooled by moving to the mold 4 and the molten steel is cooled while moving along the roll 5 to form a slab.

The tundish temperature measuring device 10 is installed in the tundish 3 and measures the temperature of the tundish 3 and wirelessly transmits the information to the control unit. An A / D converter 15 for converting a temperature into a digital signal, a wireless transmitter 16 for transmitting a signal to a control unit, and a power supply source 17 for supplying power for driving the temperature measuring device 10.

Temperature measuring module 11 is a device for measuring the temperature of the molten steel (2), can be installed to penetrate the wall of the tundish (3) to be exposed to the molten steel (2), by installing a plurality of sensors in the depth direction on the wall The temperature of the molten steel 2 can be measured through a temperature gradient depending on the depth of the wall. Specific embodiments thereof will be described with reference to FIGS. 2 and 3.

2 is a block diagram showing an embodiment of the tundish temperature measuring apparatus 10 according to an aspect of the present invention, the tundish temperature measuring apparatus 10, the temperature sensor 12, the protective tube 13, A / D converter 15, wireless transmitter 16 and power supply 17 are shown.

In this embodiment, the temperature measuring module 11 penetrates through the wall of the tundish 3, and the temperature sensor 12 is in contact with the molten steel 2, and the temperature sensor 12 is damaged from the molten steel 2. It consists of the protective pipe 13 which prevents. Materials such as composite ceramics or alumina refractories may be used because they must be able to transfer heat and prevent breakage.

3 is a block diagram showing another embodiment of the tundish temperature measuring apparatus 10 according to an aspect of the present invention, the temperature sensor 12, A / D converter (constituting the tundish temperature measuring apparatus 10 ( 15, a wireless transmitter 16 and a power supply 17 are shown.

In the present embodiment, the temperature measuring module 11 is inserted into the wall of the tundish 3 and includes a plurality of temperature sensors arranged to have a sequential height in the thickness depth direction of the wall of the tundish 3. The temperature in the thickness depth direction of the wall is different depending on the thermal conductivity of the material constituting the wall of the tundish 3.

By grasping the thermal conductivity and the heat distribution, it is possible to measure the temperature of the molten steel (2), there is an advantage that a safety device that must be equipped in order to directly reach the molten steel (2) is not required.

The temperature measurement module 11 is not limited to its arrangement and configuration as long as it can measure the temperature of the molten steel 2 by installing a temperature sensor so that it can be used stably and semi-permanently in addition to the above-described embodiment.

The A / D converter 15 is connected to the temperature measurement module 11 is installed on the outer wall of the tundish (3), and the temperature information measured by the temperature sensor is an analog method to transmit wirelessly using the A / D converter 15 Convert the digital signal to data processing.

In addition, the wireless transmitter 16 is configured as an A / D converter 15 and installed on the outer wall of the tundish 3, and controls the digital signal converted by the A / D converter 15 to the controller (see FIG. 4 to be described later). 20) to transmit. When the wireless transceiver is used, only a simple temperature measuring device needs to be checked separately, and noise due to cable damage does not occur during transmission.

Wired cables such as compensating wires have to be replaced periodically after a certain period of time due to damage or a cost burden, and if a damage occurs inside the cable, it is generally difficult to detect and must be replaced. In view of this, using a wireless transmitter has the advantage of simplifying the process and reducing maintenance costs.

Power supply 17 refers to an external energy source that converts an analog signal into a digital signal and provides the electrical energy required for wireless transmission.

Next, the tundish temperature monitoring system according to another aspect of the present invention will be described with reference to FIGS. 4 and 5.

4 is a block diagram showing an embodiment of a tundish temperature monitoring system according to another aspect of the present invention, the tundish temperature measuring device 10, the control unit 20 is shown.

For the temperature measurement module 11, the A / D converter 15, the wireless transmitter 16, and the power supply 17, which are detailed components constituting the tundish temperature measuring device 10, Since the embodiments have been described in detail, detailed descriptions will be omitted.

The control unit 20 includes a radio receiver 21, a computer 22, and a monitor 23. The radio receiver 21 is a signal including temperature information received from the radio transmitter 16, which is immediately received by the computer 22, and outputs data necessary for the continuous casting process control and determines the control method.

The monitor 23 is a device for outputting data processed by the computer 22, and outputs it using a display device so that an operator can recognize the internal molten steel 2 temperature or the temperature during preheating.

5 is a schematic view showing the position of the temperature measuring device 10 according to another embodiment of the tundish temperature monitoring system according to another aspect of the present invention, in which the tundish 3 and the plurality of temperature measuring devices 10 are provided. Is shown.

The plurality of temperature measuring devices 10 are provided on the wall and the floor according to the height of the tundish 3. The temperature measuring device 10 may detect a temperature gradient of the molten steel 2 according to a position in the tundish 3 to determine a temperature gradient inside the tundish 3.

By using the above-described temperature measuring device 10 and the temperature monitoring system, the data can be transmitted and received wirelessly, thereby improving the working environment and improving the suitability of temperature measurement, and having the advantage of lower maintenance cost than the wired cable. Noise is not generated since damage of the back is minimized.

When the molten steel (2) is contained as well as in the preheating step, the temperature gradient data can be used to control the amount of LNG gas used as a preheating raw material to effectively preheat.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It will be understood that the invention may be varied and varied without departing from the scope of the invention.

1: ladle 2: molten steel
3: tundish 4: mold
5: roll 6: sliding nozzle
10: tundish temperature measuring device 11: temperature measuring module
12,14: temperature sensor 13: protective tube
15: A / D Converter 16: Wireless Transmitter
17: power supply 20: control unit
21: wireless receiver 22: computer
23: monitor

Claims (9)

A temperature measurement module installed on a wall of a tundish and measuring a temperature of the molten steel stored in the tundish;
An A / D converter for converting temperature information on the temperature measured by the temperature measuring module into a digital signal;
And a wireless transmitter for transmitting the signal to a control unit. The method of claim 1,
The temperature measurement module
And a temperature sensor inserted through the wall of the tundish and protected from the heat of the molten steel by a protective tube. The method of claim 1,
The temperature measurement module
Inserted into the wall of the tundish
And a plurality of temperature sensors arranged to have a sequential height in the thickness depth direction of the wall of the tundish. The method of claim 1,
The A / D converter and the wireless transmitter
Tundish temperature measuring device, characterized in that installed on the outer wall of the tundish. A temperature measuring device including a temperature measuring module for contacting a wall of a tundish and measuring a temperature of the molten steel stored in the tundish, an AD converter for converting the temperature measured by the temperature measuring module into a signal, and a wireless transmitter for transmitting the signal to a controller. ;
A wireless receiver for receiving the transmitted signal; And
A tundish temperature monitoring system comprising a control unit for monitoring the temperature of the tundish using the data received from the wireless receiver. The method of claim 5,
The temperature measuring device is provided with a plurality of the height of the tundish on the wall and the bottom of the tundish,
The control unit
A tundish temperature monitoring system, comprising calculating a temperature gradient inside the tundish using data received from the plurality of temperature measuring devices. The method of claim 5,
The temperature measurement module
And a temperature sensor inserted through a wall of the tundish and protected from heat of molten steel by a protective tube. The method of claim 5,
The temperature measurement module
Inserted into the wall of the tundish
And a plurality of temperature sensors arranged to have a sequential height in the thickness depth direction of the wall of the tundish. The method of claim 5,
The A / D converter and the wireless transmitter
Tundish temperature monitoring system, characterized in that installed on the outer wall of the tundish.

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