JP2017179577A - Method for operating melting-refining furnace and melting-refining furnace - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for operating a melting-refining furnace, upon the operation of a melting-refining furnace for a cold iron source using oxygen burner(s)-lance(s), improving the efficiency.SOLUTION: Provided is a method for operating a melting-refining furnace where, in a furnace equipped with a through hole provided so as to pass through a furnace wall, one or more burners provided in the through hole and one or more lances installed in a combustion supporting fluid feed hole provided at the part upper than the through hole for a burner, operation is performed in such a manner that the introduction amount of oxygen lies in a range calculated from the volume of the furnace in a melting step.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a method for operating a melting and refining furnace for a cold iron source using an oxygen burner and a lance, and a melting and refining furnace.

  Burners that heat an object to be heated by burning a combustion-supporting fluid (oxygen, air, oxygen-enriched air, etc.) containing oxygen and fuel are used in various production processes. For example, in a steelmaking process in an electric furnace, when a raw material such as iron scrap is heated and melted in the electric furnace, a low temperature region called a cold spot is generated in the raw material, and the raw material may be difficult to melt in this part. . In such a case, the combined use of a burner as disclosed in Patent Document 1 can increase the heating efficiency of the raw material, reduce the amount of power used for melting the raw material, and reduce the melting cost. .

  In addition, a part of the raw material can be oxidized and melted by the combustion-supporting fluid to promote cutting, and the heating efficiency of the raw material can be further increased. Furthermore, it is possible to promote combustion of an unburned fluid (such as carbon monoxide) by supplying a combustion-supporting fluid.

  For example, Patent Document 2 discloses an invention that uses oxygen gas preheated to a high temperature in advance in order to increase the heating efficiency during secondary combustion with a combustion-supporting fluid.

Japanese Patent No. 4050195 JP 2000-337776 A

In such an operation, since the auxiliary melting of the raw material by the burner is aimed at reducing the melting cost, the consumption of the combustion-supporting fluid blown into the electric furnace is minimized and the yield is improved. There is also a demand for suppression of peroxidation of raw materials. The present invention has been made in view of the above circumstances, and is to improve the efficiency of a cold iron source melting / smelting furnace operation or refining using a burner and a lance.

The melting and refining method of the present invention for solving the above problems is a method of melting and refining a cold iron source using an electric furnace, the first step of charging the cold iron source from the upper part of the electric furnace, A second step in which the cold iron source is mainly melted by energizing an electrode provided in the center of the electric furnace, a third step in which the cold iron source is auxiliary melted by a burner provided in the furnace wall of the electric furnace, and an upper portion from the burner. From the lance installed in the oxygen ejection hole provided in the furnace wall at the position of the above, oxygen is ejected downward from the horizontal direction, and the oxygen and carbon monoxide and / or hydrogen generated when the cold iron source is dissolved It comprises a melting step consisting of a fourth step to be reacted, and a refining step of removing impurities by introducing oxygen into the molten ore generated by melting the cold iron source.
The fourth step starts at the same time as or immediately after the start of the third step and ends with the start of the refining step. The furnace volume V (m ³ ) and the amount of oxygen Q (Nm ³ / h) to be introduced A cold iron source melting and refining method characterized in that the relationship is in the range of V / Q = 0.1 to 0.8.

The melting / smelting furnace of the present invention is a furnace for carrying out the melting and smelting method, wherein the furnace is an electric furnace having an opening for introducing a cold iron source at an upper portion thereof, The electric furnace has an electrode for melting a cold iron source at the center thereof, a burner for auxiliary melting of the cold iron source at the furnace wall, and oxygen is introduced into the furnace wall at a position above the burner. And an oxygen flow rate adjusting mechanism for supplying a constant amount of oxygen to the lance, and the mounting positions of the burner and the lance on the furnace wall are in the following ranges. It is a melting and smelting furnace for cold iron sources.
Distance L ₁ from the molten metal surface to the tip of the burner <Distance L ₂ from the molten metal surface to the tip of the lance
Angle α between burner center axis and horizontal plane ≧ Angle β between lance central axis and horizontal plane
Angle α> 0 ° between the central axis of the burner and the horizontal plane
The angle between the central axis of the lance and the horizontal plane β ≧ 0 °

The oxygen flow rate adjustment mechanism is a cold iron source melting / smelting furnace comprising a flow rate control valve, a flow rate indicator, a pressure gauge, and a pressure control valve.

  According to the present invention, when operating or refining a cold iron source using a burner and a lance, it is possible to inject an appropriate amount of a supporting fluid from an appropriate position into the furnace. Since the consumption of the ionic fluid can be minimized, the dissolution efficiency can also be improved.

It is a schematic diagram of the melting and smelting furnace used in the present invention. It is a schematic diagram at the time of removing the upper cover of the melting / smelting furnace used in the present invention and introducing a cold iron source. It is the schematic diagram which showed arrangement | positioning of the burner and lance from the electric furnace side surface. It is the schematic diagram which showed arrangement | positioning of the burner from an electric furnace upper part. It is a schematic diagram of the burner (burner lance) which has a lance function in embodiment. It is a schematic diagram of the flow control mechanism of oxygen supplied from the lance into the furnace. It is a figure showing the relationship between the generation amount of carbon monoxide and hydrogen in the exhaust gas from the melting / smelting furnace and the furnace volume V ₁ / the introduced oxygen amount Q. It is a figure showing the relationship between the generation amount of carbon monoxide and hydrogen in the exhaust gas from the melting / smelting furnace, and the furnace volume V ₂ / introduced oxygen amount Q.

An embodiment of the present invention will be described. A cold iron source melting and smelting furnace used in the present invention is shown in FIG. The melting / smelting furnace 1 shown in FIG. 1 is an electric furnace having an electrode 4 at the center thereof. The electric furnace 1 has a cylindrical shape whose upper part can be opened, and has a furnace lid 3 that closes the opening of the furnace. Although there are cases where there are one electrode and three electrodes 4 depending on each furnace, in the present embodiment, a case where there is one electrode is shown.

When the cold iron source is put into the electric furnace 1, for example, as shown in FIG. 2, the electrode is pulled out, the furnace cover is removed, and then the cold iron source is put in through the opening at the top of the furnace body 2.

The electric furnace 1 has a through hole 5A provided so as to penetrate the furnace wall 2A, and a burner 3 is installed in the through hole 5A. The furnace wall 2A is provided with a combustion-supporting fluid through hole 6A above the through hole 5A so as to penetrate the furnace wall 2A. A lance 6 is installed in the combustion-supporting fluid through hole 6A in order to introduce a combustion-supporting fluid (oxygen) into the furnace. The burner 5 is inserted from the through-hole 5A, and the lance 6 is inserted from the combustion-supporting fluid through-hole 6A toward the furnace bottom 2B and fixed.

FIG. 3 is a view showing the arrangement of burners and lances from the side of the electric furnace. The installation position of the lance 6 on the furnace wall 2 </ b> A is above the burner 5. That is, when L ₁ is the height position of the burner 5 (distance between the burner tip and the molten metal surface) and L ₂ is the height position of the lance 6 (distance between the lance tip and the molten metal surface), L ₁ < The burner 5 and the lance 6 are installed so as to be L ₂ (the left figure in FIG. 3). Here, the molten metal surface means the upper surface of the molten metal formed from molten steel after melting the cold iron source.

The installation direction of the burner 5 is fixed so that 90 °> α> 0 °, where α is the angle formed by the central axis of the burner 5 and the horizontal direction (right diagram in FIG. 3). More preferably, 60 ° <α <45 °. In addition, the installation direction of the lance is fixed so that α ≧ β ≧ 0 °, where β is an angle formed between the central axis of the lance 6 and the horizontal direction (the right diagram in FIG. 3). That is, the ejection direction of the combustion-supporting fluid from the lance 6 is set to the same angle or more as the direction in which the flame by the burner 5 is formed. By setting the direction of the lance 6 in this way, the unburned gas (mainly carbon monoxide and hydrogen) when the burner 5 is burned can be efficiently burned by the combustion-supporting gas from the lance 6. Can do.

FIG. 4 is a view showing the arrangement of the burner 5 from the upper part of the electric furnace. FIG. 4 shows an example in which three burners are installed. The flame formation direction of the burner 5 is directed to a direction in which a place where the heating of the cold iron source by the electrode 4 is insufficient in the furnace can be heated. In order not to damage the electrode 4, it is desirable to install the burner 5 so that the flame does not directly hit the electrode.

FIG. 5 shows a schematic cross-sectional view showing the configuration of the burner in the present embodiment. The burner described in FIG. 5 is a burner having a lance function (burner lance). A combustion support fluid supply pipe 18 that supplies a support fluid containing oxygen is provided at the center of the oxygen burner lance 6 in the present embodiment, and a fuel fluid that supplies fuel fluid is provided on the outer periphery thereof. A supply pipe 19 is provided, and a combustion-supporting fluid supply pipe 20 is provided concentrically on the outer periphery thereof. A reflux type water cooling jacket 21 is provided on the outer periphery of the combustion-supporting fluid supply pipe 20.

  In addition, the reflux-type water cooling jacket 21 may be provided on the outer periphery of the fuel fluid supply pipe 19 without providing the fuel support fluid supply pipe 20, but when the fuel support fluid supply pipe 20 is provided, the fuel support property is improved. The flame length can be adjusted by adjusting the oxygen flow rate ratio between the fluid supply pipes 18 and 20.

  The combustion-supporting fluid supply pipe 18 includes a large-diameter portion 18a having a constant inner diameter, a throat portion 18b having a smaller inner diameter than the large-diameter portion 18a, and a distal-end side from the throat portion 18b. An expanded portion 18c having an inner diameter gradually increasing toward 18B and a linear motion portion 18d having a substantially constant inner diameter are provided.

In the upper part of the furnace wall 2A where the burner lance (burner 5) is installed in the present embodiment, a combustion support for installing a lance 6 for introducing a combustion supporting fluid containing oxygen for secondary combustion into the furnace. A functional fluid supply hole 6A is provided.
The lance 6 is desirably provided with a reflux water cooling jacket on the outer periphery of a combustion-supporting fluid supply pipe for supplying a combustion-supporting fluid containing oxygen. A lance having a water cooling jacket can be installed regardless of whether the furnace wall is a refractory wall or a water cooling wall.

FIG. 6 shows a configuration of an oxygen flow rate adjusting mechanism for supplying oxygen to the lance 6. The oxygen flow rate adjusting mechanism includes a pressure control valve 10, a pressure gauge 11, a flow rate indicator 12, and a flow rate control valve 13 from the oxygen supply side.

A method of melting and refining a cold iron source using the melting / smelting furnace 1 as described above will be described. First, as shown in FIG. 2, a cold iron source is supplied from the upper opening of the furnace body 2 from which the electrode 4 and the furnace lid 3 are removed (first step). Next, the electrode 4 is lowered to a predetermined position in the center of the melting / smelting furnace 1, and the upper part of the furnace body 2 is covered with the furnace lid 3. And it supplies with electricity to the electrode 4 and melt | dissolves a cold iron source (2nd process).
When the melting of the cold iron source begins and the molten metal begins to accumulate in the furnace bottom 2B, the cold iron source is auxiliary melted by a plurality of burners 5 provided on the furnace wall 2A of the melting / smelting furnace 1 (third step).
At the same time as the start of the third step or immediately after that, oxygen is spouted from the lance 6 installed in the combustion-supporting fluid supply hole 6A provided in the furnace wall 2A, and carbon monoxide generated when the cold iron source is dissolved. And / or reacting with hydrogen (fourth step).
The first step to the fourth step are dissolution steps.

Here, the amount of oxygen supplied from the lance 6 in the fourth step can be determined from the volume of the melting / smelting furnace 1. That is, when the volume of the melting / smelting furnace 1 is V (m ³ ), the oxygen introduction amount Q (Nm ³ / h) in the fourth step is V / Q = 0.1 to 0.8. Try to be in range. Here, the furnace volume V is the internal volume of the furnace body 2 before the cold iron source is charged.

When the cold iron source is almost melted in the melting process and the molten steel is melted in the furnace bottom, the fuel supply to the burner lance (burner 5) is stopped and the lance mode is switched to introduce oxygen into the molten metal. To remove impurities. This is the refining process.

In the melting and refining furnace in which the internal volume of the furnace body is V ₁ (m ³ ), the melting process (the first process to the fourth process) was performed. At the exhaust gas outlet of the melting and smelting furnace, an exhaust gas analyzer and an exhaust gas flow rate measuring device (not shown) are provided, and in the third step, when oxygen gas is introduced from the lance into the furnace, monoxide in the exhaust gas The contents of carbon and hydrogen (CO, H ₂ ) can be measured.

In the third step, the oxygen amount Q (Nm ³ / h) introduced into the furnace from the lance 6 is changed using an oxygen flow rate adjusting mechanism, so that carbon monoxide and hydrogen are contained in the exhaust gas from the melting and refining furnace. The amount was measured. The result is shown in FIG.
The horizontal axis in FIG. 7 is V ₁ / Q. The vertical axis represents the generation amount (Nm ³ / t) of carbon monoxide and hydrogen (CO, H ₂ ) per 1 t of iron obtained by dissolving the cold iron source.
When V ₁ / Q was 0.1 to 0.8, it was confirmed that the amount of CO and H ₂ generated decreased as the amount of oxygen introduced increased. However, when V ₁ / Q becomes 0.8 or more, the concentrations of CO and H ₂ hardly change. That is, it indicates that the amount of oxygen to be introduced is insufficient, and it is understood that secondary combustion is not sufficiently performed. It was also confirmed that when the amount of oxygen introduced was increased below 0.1, there was no significant change in the amount of CO and H ₂ generated.

A similar test was conducted in a melting / smelting furnace (furnace volume V ₂ ) different from the above. The results are shown in FIG. When V ₂ / Q was 0.1 to 0.8, an effect of reducing carbon monoxide and hydrogen according to the amount of oxygen introduced from the lance 6 was observed. That is, an appropriate amount of oxygen introduced without waste is when V ₂ / Q is in the range of 0.1 to 0.8.

  The melting / smelting furnace operating method and melting / smelting furnace of the present invention can be used for melting a cold iron source in an electric furnace.

DESCRIPTION OF SYMBOLS 1 ... Melting / smelting furnace (electric furnace), 2 ... Furnace body, 2A ... Furnace wall, 2B ... Furnace bottom, 3 ... Furnace lid, 4 ... Electrode, 5 ... Burner (burner lance), 5A ... through hole, 6 ... lance, 6A ... flammable fluid supply hole, 10 ... pressure regulating valve, 11 ... pressure gauge, 12 ... -Flow indicator, 13 ... Flow control valve, 18 ... Fuel support fluid supply pipe, 19 ... Fuel fluid supply pipe, 20 ... Fuel support fluid supply pipe, 21 ... Reflux type Water cooling jacket

Claims (3)

A method for melting and refining a cold iron source using a melting and smelting furnace,
A first step of charging a cold iron source from the upper part of the melting / smelting furnace;
A second step of energizing an electrode provided at the center of the melting / smelting furnace to mainly melt the cold iron source and a second step of auxiliary melting of the cold iron source by a burner provided on the furnace wall of the melting / smelting furnace. 3 steps,
Using a lance from a combustion-supporting fluid jet hole provided at a position above the burner on the furnace wall, the support-supporting fluid and the cold iron source are ejected from the horizontal direction downward. A melting step comprising a fourth step of reacting carbon monoxide and / or hydrogen generated during melting, and a refining step of removing impurities by introducing oxygen into the ore produced by melting the cold iron source Become
The fourth step starts at the same time as or immediately after the start of the third step, ends with the start of the refining step, and when the furnace body volume of the furnace is V (m ³ ), Melting and refining a cold iron source characterized in that the oxygen introduction amount Q (Nm ³ / h) when the combustion supporting fluid in the process is oxygen is in the range of V / Q = 0.1 to 0.8 Method. A furnace for melting and smelting a cold iron source,
The furnace is an electric furnace having an opening for introducing a cold iron source in the upper part,
The electric furnace has an electrode for melting a cold iron source at the center thereof,
A burner for auxiliary melting of the cold iron source in the furnace wall;
A lance for introducing oxygen into the furnace wall at a position above the burner;
An oxygen flow rate adjusting mechanism for supplying a constant amount of oxygen to the lance,
The cold iron source melting / smelting furnace, wherein the burner and the lance are attached to the furnace wall in the following ranges.
Distance L ₁ from the molten metal surface to the tip of the burner <Distance L ₂ from the molten metal surface to the tip of the lance
Angle α between burner center axis and horizontal plane ≧ Angle β between lance central axis and horizontal plane
Angle 90 °>α> 0 ° formed by the central axis of the burner and the horizontal plane
The angle between the central axis of the lance and the horizontal plane β ≧ 0 ° The melting / smelting furnace for a cold iron source according to claim 2, wherein the oxygen flow rate adjusting mechanism comprises a flow rate control valve, a flow rate indicator, a pressure gauge, and a pressure control valve.