KR20130059793A - Apparatus for preventing scale of materials - Google Patents

Abstract

PURPOSE: A scale prevention device is provided to accept a rolling roll to cut-off an accepting unit from the outside and to prevent scale occurrence with respect to a material for passing a rolling roll by injecting inert gas into the accepting unit by an oxygen free unit to form an oxidation atmosphere. CONSTITUTION: A scale prevention device comprises an accepting unit and an oxygen free unit. The accepting unit accepts a rolling roll(2) and is cut off from the outside. The accepting unit injects inert gas into the accepting unit by an oxygen free unit to form an oxidation atmosphere. The scale prevention device prevent scale occurrence with respect to a material(1) for passing a rolling roll. The oxygen free unit comprises a gas injection nozzle(30) and an air outlet(40). The gas injection nozzle is mounted on the accepting unit and is connected to a gas supply line(31) to inject the inert gas. The air outlet discharges air inside the accepting unit.

Description

Apparatus for preventing scale of materials}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a scale preventing device, which prevents the generation of scale on the surface of a material during rolling.

The rolling process is a process of passing a slab through rotating rolls to produce a strip.

In general, the rolling process consists of rough rolling and finishing rolling.

Rough rolling ensures that the descaled slab is of appropriate shape, thickness, and width, and finishing rolling produces the slab into strips of defined thickness and width, and has a good surface shape at the finishing temperature for the intended use.

Here, although the scale is removed through rough rolling, a fine scale is generated on the surface of the strip in the course of passing through the rough rolling.

This is because the oxygen contained in the air reacts on the surface of the strip, and the surface of the strip is oxidized.

As a result, the surface of the strip is degraded due to the scale, and there is a limitation in that it is necessary to further input the strip into the descaling process.

The present invention has been made to solve the above problems, by forming a low-oxygen rolling atmosphere, that is, an anoxic atmosphere at the beginning of the rolling to suppress the diffusion of the scale layer on the surface of the material, thereby creating scale generation of the surface of the material during rolling It is an object of the present invention to provide a scale preventing device.

In order to achieve the above object, a scale preventing device according to a preferred embodiment of the present invention includes a receiving means configured to receive a rolling roll but block it from the outside; And an oxidation-free means for injecting an inert gas into the receiving means to form an oxygen-free atmosphere. Inhibiting scale generation of the material passing through the rolling roll.

At this time, the oxidation-free means, the gas injection nozzle is mounted to the receiving means and connected to the gas supply line for injecting inert gas; And an air outlet through which the air in the receiving means is discharged.

The oxidation-free means may further include a gas curtain nozzle installed at each of the inlet and outlet portions through which the material passes through the accommodating means and connected to a gas supply line to inject an inert gas.

In addition, the air outlet is mounted to the upper portion of the receiving means, the non-oxidation means is preferably further provided with a gas outlet for discharging the inert gas in the lower portion of the receiving means.

At this time, the gas injection nozzle and the gas curtain nozzle are in communication with the gas supply line, respectively, the gas supply line, the air outlet, and the gas outlet is equipped with a valve, the sensor for measuring the oxygen concentration in the receiving means is mounted Preferably, the valve and the sensor are controlled in electrical connection with the device control unit.

The receiving means includes a roll housing in which the rolling roll is accommodated; And a connecting housing for communicating the plurality of spaced roll housings, wherein the roll housing and the connecting housing are modular and detachable from each other.

At this time, it is preferable that the said rolling roll is a finishing rolling roll, and the said accommodating means accommodates three front sides of the finishing rolling roll successively.

The scale preventing device according to the present invention includes a receiving means configured to receive a rolling roll but block the outside, and an oxidation-free means for injecting an inert gas into the receiving means to form an oxygen-free atmosphere, thereby passing through the rolling roll. It has the effect of suppressing the generation of scale for the material.

As such, when a low oxygen rolling atmosphere or an anoxic atmosphere is formed at the beginning of rolling to suppress diffusion of the scale layer on the surface of the material, scale blistering occurs almost on the surface of the material even if the oxidation time is increased during the high temperature rolling process. By not doing so, the quality of the material does not fall even after rolling, which has the advantage of making a high quality material.

FIG. 1 is a graph showing the change in scale layer thickness with oxygen concentration.
FIG. 2 is a graph showing the state of the material surface, that is, the degree of generation of scale blisters according to the scale thickness before rolling.
3 is a view showing a scale preventing apparatus according to a preferred embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings.

1 is a graph showing the change in scale layer thickness according to the oxygen concentration.

Referring to the drawings, the graph shows the scale amount (mg / cm 2) per unit area of the material according to the oxidation time in each gas atmosphere with oxygen concentrations of 1%, 3%, 6%, 12%, and 15%. It is a graph.

That is, the graph controls the concentration of oxygen during rolling to show the scale amount per unit area, that is, the thickness of the scale layer according to the concentration of oxygen.

At this time, in the gas atmosphere containing 1% oxygen having the smallest oxygen concentration, the increase rate of the scale per unit area was the lowest even if the oxidation time was increased.

In other words, the lower the concentration of oxygen during rolling, the thinner the scale layer was. In addition, when the oxidation time was gradually increased, the degree of thickening of the scale layer was relatively remarkable as the oxygen concentration was gradually increased. The rate of increase was low.

In particular, in the oxidation time for the first minute in the range of the dotted line, that is, in the initial rolling process, the lower the concentration of oxygen, the less the amount of scale, which depends on the concentration of oxygen in the initial rolling process. The rate of increase begins to vary. This difference leads to a large difference in the amount of scale as the oxidation time increases.

In other words, as the thickness of the scale becomes thinner in the initial rolling process, it can be seen that generation of scale is suppressed even in the process of gradually rolling.

As a result, it can be seen that when the concentration of oxygen is initially high during the rolling process, the scale layer becomes thicker at a high rate of increase as the oxidation time is increased due to exposure to air during the subsequent rolling process.

On the contrary, if the concentration of oxygen is initially low during the rolling process, the scale layer thickens at a low rate of increase even if the oxidation time is gradually increased due to exposure to air during the subsequent rolling process. There was little change.

In this way, the thickness of the scale in the subsequent rolling process is different according to the initial concentration of oxygen in the rolling process. At the beginning of the rolling process, a low oxygen rolling atmosphere is formed through partial sealing or blocking to reduce the thickness of the scale layer. It can be seen that.

2 is a graph showing the state of the material surface according to the scale thickness before rolling, that is, the degree of occurrence of scale blisters.

Referring to the drawings, the graph shows the surface state of the material according to the rolling temperature and the thickness of the scale before rolling.

In this case, '○' indicates a smooth surface state of the material, '△' indicates a state where there is a little crack on the material surface, and '×' indicates a rough surface state of the material.

As a result of this, even in high-temperature rolling, the thinner the thickness of the scale before rolling, the smoother the surface state was maintained.

In other words, '○' is often displayed when the thickness of the scale is thin during the high temperature rolling process. When the high temperature rolling process is started with the thin thickness of the scale, the scale blister appears on the surface layer of the material. It rarely occurs.

As a result, when the thickness of the scale is maintained on the surface of the material at the beginning of the rolling is less than 6㎛ ~ 8㎛, even after the high temperature rolling process, the surface of the material is smooth, that is, the scale blister hardly occurs Done.

As described above with reference to FIGS. 1 and 2, when a low-oxygen rolling atmosphere is formed at the beginning of the rolling to suppress diffusion of the scale layer on the surface of the material, even if the oxidation time is increased during the hot rolling process, the scale bliss is formed on the surface of the material. Since no burr is generated, the quality of the material does not deteriorate even after rolling.

Accordingly, in order to form the low oxygen rolling atmosphere as described above, the present invention provides a scale preventing device as shown in FIG. For reference, since it is difficult to make a vacuum state through the completely closed during the initial rolling, there is little blister on the surface layer of the material through a low oxygen rolling atmosphere.

3 is a view showing a scale preventing apparatus according to a preferred embodiment of the present invention.

Referring to the drawings, the present invention includes an accommodating means in which the rolling roll 2 is accommodated, and an anoxic means for forming an oxygen free atmosphere in the accommodating means. At this time, rolling is performed while the material passes between the rolling rolls 2, and then proceeds by the table roll 3.

Here, the rolling roll (2) is a finishing rolling roll as an example, it is preferable that the receiving means is subsequently accommodated three front sides of the finishing rolling roll in order to form an oxidation-free atmosphere during the initial rolling.

The accommodating means has a shape that surrounds the rolling roll 2 so that the rolling roll 2 is positioned inside and blocked from the outside, and the material is rolled while wrapping the upper rolling roll 2 and the lower rolling roll 2 as a whole. The inlet part 23 and the outlet part 24 are formed so that (1) may pass.

Specifically, the accommodation means may include a roll housing 21 in which the rolling roll 2 is accommodated, and a connection housing 22 for communicating the plurality of spaced roll housings 21.

Here, the roll housing 21 is to block the outside in the process of the material 1 is rolled by the rolling roll 2, the connecting housing 22 is between the rolling roll 2 and the rolling roll (2) In the process of passing through the role to be blocked from the outside.

Further, it is preferable that the roll housing 21 and the connecting housing 22 are detachable from each other in a modular form. As a result, the roll housing 21 and the connecting housing 22 can be easily and conveniently removed and repaired or replaced even when damaged.

In addition, the non-oxidizing means is configured to inert gas into the receiving means to form an oxygen-free atmosphere, this oxidation-free means serves to suppress the generation of scale for the material (1) passing through the rolling roll (2) Do this.

Specifically, the non-oxidation means has a gas injection nozzle 30 which is mounted to the receiving means and injects inert gas, and an air outlet 40 for discharging air in the receiving means.

At this time, the gas injection nozzle 30 is in communication with the gas supply line 31 is supplied with an inert gas, preferably may be mounted on the upper portion of the receiving means.

When the inert gas that is heavier than air is injected through the gas injection nozzle 30, the inert gas flows downward in the receiving means in the process of inflow and flow of the inert gas, so that the receiving means becomes an inert atmosphere as a whole. .

In addition, the air discharge port 40 is the air discharged in the receiving means, when the inert gas is introduced into the receiving means through the gas injection nozzle 30 is a passage for gradually being pushed out to the outside.

At this time, the air outlet 40 may be preferably mounted on the upper portion of the accommodating means, which gradually accumulates from the lower side of the accommodating means when an inert gas that is heavier than air such as argon (Ar) is introduced through the gas injection nozzle 30. As it rises, the air is pushed up by the inert gas so that it can be smoothly discharged to the outside by the air outlet 40 mounted on the upper portion of the receiving means.

In addition, the non-oxidation means may further include a gas discharge port 50 through which an inert gas is discharged under the receiving means.

The gas discharge port 50 may selectively open and withdraw when there is a case to remove the inert gas introduced into the receiving means to the outside.

Here, the above-described gas injection nozzle 30 and the gas discharge port 50 is preferably mounted on the upper and lower portions of the connecting housing 22, respectively, in the receiving means, the passage through which the material 1 is transferred when inert gas is introduced. The phosphor may be flowed from the connecting housing 22 to the roll housing 21 and filled.

In addition, the oxidation-free means may be further provided with a gas curtain nozzle 60 which is installed at the inlet 23 and the outlet 24 through which the raw material 1 passes in the receiving means to inject inert gas. At this time, the gas curtain nozzle 60 is in communication with the gas supply line 61 is supplied with an inert gas.

The receiving means has to have a structure in which both ends are opened for the material 1 to be conveyed, and the outside air through the open part, that is, the inlet 23 and the outlet 24 of the material 1 to be conveyed. Can be introduced.

Accordingly, the gas curtain nozzle 60 injects an inert gas from the inlet portion 23 and the outlet portion 24 of the accommodating means toward the material 1 and forms the surroundings in an inert gas atmosphere. It will act as a curtain to prevent it from happening.

That is, the gas curtain nozzle 60 is sprayed toward the material 1 from the upper side and the lower side of the raw material 1 conveyed from the inlet 23 and the outlet 24 of the receiving means, respectively, so that Since the space is isolated from the outside of the receiving means, it is possible to prevent the inflow of air from the outside.

On the other hand, the gas injection nozzle 30 and the gas curtain nozzle 60 is in communication with the gas supply line 31, 61, respectively.

At this time, the gas supply line 31, 61, the air discharge port 40, and the gas discharge port 50 is respectively equipped with a valve (V), the sensor (S) for measuring the oxygen concentration in the receiving means is Is mounted.

Here, the valve (V) and the sensor (S) can be controlled in electrical connection with the device control unit (C).

Accordingly, the valve V may be selectively opened and closed while controlling the gas supply flow rates of the gas supply lines 31 and 61 to perform gas supply and shutoff, and the air outlet 40 and the gas outlet 50. The selective opening and closing allows the air and gas to be discharged or blocked.

In addition, by measuring the oxygen concentration in the accommodating means by the sensor (S) to determine the oxygen concentration in the accommodating means can be utilized as data for the injection of inert air.

Furthermore, both the valve V and the sensor S are electrically connected to the apparatus control unit C, thereby controlling the opening and closing of each valve V with the measurement data by the sensor S, thereby stably and efficiently The scale prevention device can be operated.

The present invention configured as described above, the rolling roll (2) is accommodated, but the receiving means is configured to block the outside, and by injecting an inert gas into the receiving means to form an oxidation-free atmosphere by rolling, Scale generation with respect to the raw material 1 passing through the roll 2 can be suppressed.

As such, when a low-oxygen rolling atmosphere, that is, an anoxic atmosphere is formed at the beginning of rolling to suppress diffusion of the scale layer on the surface of the material 1, even if the oxidation time is increased during the high temperature rolling process, the surface of the material 1 Since the scale blister hardly occurs, the quality of the raw material 1 does not deteriorate even after rolling, and the high quality raw material 1 can be produced.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

21: roll housing 22: connection housing
23: inlet 24: outlet
30: gas injection nozzle 31, 61: gas supply line
40: air outlet 50: gas outlet
60: gas curtain nozzle V: valve
S: Sensor C: Control Unit

Claims (7)

Receiving means is configured to accommodate the rolling roll 2 but to block the outside; And an oxidation-free means for injecting an inert gas into the accommodation means to form an oxygen-free atmosphere.
A scale preventing device, characterized in that to suppress the generation of scale for the raw material (1) passing through the rolling roll (2).
The method of claim 1,
The oxidation-free means includes: a gas injection nozzle 30 mounted to the receiving means and connected to a gas supply line 31 to inert an inert gas; And an air discharge port 40 through which air in the accommodation means is discharged.
Scale prevention device characterized in that it comprises a.
The method of claim 2,
The oxidation-free means, the gas curtain nozzle is installed in the inlet portion 23 and the outlet portion 24 through which the material 1 passes in the receiving means and connected to the gas supply line 61 to inject an inert gas 60;
Scale prevention device further comprising.
The method of claim 3,
The air outlet (40) is mounted to the upper portion of the receiving means, the non-oxidation means is a scale prevention device further comprises a; gas outlet (50) for discharging the inert gas in the lower portion of the receiving means.
5. The method of claim 4,
The gas injection nozzle 30 and the gas curtain nozzle 60 communicate with the gas supply lines 31 and 61, respectively, and the gas supply lines 31 and 61, the air discharge port 40, and the gas discharge port ( 50 are each equipped with a valve (V),
Sensor (S) for measuring the oxygen concentration is mounted in the receiving means, the valve (V) and the sensor (S) is a scale prevention device, characterized in that the electrical control is connected to the device control unit (C).
The method of claim 1,
The accommodating means includes: a roll housing 21 in which the rolling roll 2 is accommodated; And a connecting housing 22 for communicating the plurality of spaced roll housings 21.
The roll housing (21) and the connecting housing (22) is a scale preventing device, characterized in that detachable from each other in a modular form.
7. The method according to any one of claims 1 to 6,
The rolling roll (2) is a finishing rolling roll, and the receiving means is a scale preventing device, characterized in that for receiving the three front sides of the finishing rolling roll subsequently.

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