KR100797959B1 - A DEVICE OF INSERTING TiO2 INTO FURNACE - Google Patents

Abstract

The present invention relates to a device for injecting a large amount of titanium dioxide into the tuyere in order to reduce the wear of the lower refractory of the furnace, comprising: An air branch unit for inputting air, storing the air at a proper pressure, and performing a regulator to output a charging air and a blown air, respectively; A hopper unit for storing only the spectroscopic stones having a predetermined size or less and passing the same, so as not to pass and not accumulate in one place; A tank unit configured to uniformly disperse the spectral stones inputted from the hopper unit and accumulate and accumulate the spectral stones by charging air supplied from the air branch unit and maintaining the pressure state when the spectral stones are stored in a constant weight; A mixing unit for introducing and dispersing the spectroscopic stones stored in the tank unit by the reduced rotational force of the tank and mixing the air with the air; The effect of facilitating the quantitative discharge of the titanium dioxide (TiO2) spectroscopy from the storage tank by a feature comprising a blowing unit for mixing the spectroscopy supplied from the mixing unit with the blowing air again and introduced into the air vents, and a large amount of dioxide It is effective to control the titanium spectroscopy to be blown into the furnace vent without clogging.

Description

Titanium dioxide input device of furnace blast furnace {A DEVICE OF INSERTING TiO2 INTO FURNACE}

1 is a functional configuration diagram of a titanium dioxide input device of the furnace tuyere according to the prior art,

2 is a functional configuration of the titanium dioxide input device of the furnace tuyere according to the present invention,

3 is a detailed functional configuration diagram of the hopper section, tank section, mixing section, blowing section according to the present invention,

4 is a detailed configuration state of the mixing portion and the blowing portion of the present invention,

5 is a detailed configuration state of the screw for quantitatively discharging the spectroscopy of the present invention,

6 is an explanatory diagram illustrating a process in which spectroscopy is mixed with air in a mixing unit of the present invention;

7 is a state diagram of the spectral stone rotation in the mixing section according to the present invention,

8 is a flowchart illustrating the operation of the titanium dioxide injector in the furnace tuyere according to the present invention.

          ** Explanation of symbols on the main parts of the drawing **

A1: Air main valve A2, P4, A7, H6: Pressure gauge

A3: drain valve A4: branch cylinder                 

F1: Mixing air valve F2: Mixing pipe

F2-1: Mixing Rod F3: Feeding Valve

F3-1: Feeding Line F4: Screw Motor

F4-1: Reducer F6: Furnace

H1: Charging hopper H1-1: Mesh screen

H2: Hopper Valve H2-1: Hopper Vibrator

H3: Storage tank H3-3: Tank vibrator

H3-4: Flexible air unit H4: Load cell guide

H5: load cell 10: titanium dioxide spectroscopy

11 screw 12 packing

13: Fixing bolt 14: Bolt

15: connecting plate 16: sealing pipe

100: air branch portion 200: hopper portion

300 tank portion 400 mixing portion

500: blowing section

The present invention relates to a device for injecting titanium dioxide in order to reduce the wear of the lower refractory of the furnace, and more particularly, to a device for injecting a large amount of titanium dioxide through the tuyere.

Furnace or blast furnace is a kind of vessel to produce the molten iron by removing the slag from the molten melt of the iron ore charged from the upper side by the high temperature and high pressure hot air supplied from the lower tuyere. Reaction vessel.

Melting melted at a high temperature in the furnace is accumulated in the lower portion, the erosion occurs in the refractory constituting the lower portion of the furnace by the melted melt as described above, the method of prolonging the life of the furnace is to suppress the erosion of the refractory in the furnace lower do.

As a method of suppressing refractory erosion of the furnace as described above, when a spectroscopy containing titanium dioxide (TiO 2) is introduced through the tuyere, the titanium (Ti) component reacts with carbon (C) and nitrogen (N) in the furnace. To form a layer of the Ti (C, N) compound, and the above compound protects the refractory of the furnace to extend the life of the furnace.

Hereinafter, with reference to the accompanying drawings, a titanium dioxide input device of the furnace tuyere according to the prior art.

Attached to explain the prior art, Figure 1 is a functional configuration of the titanium dioxide input device of the furnace tuyere according to the prior art.

As shown in FIG. 1, it is generally used according to the prior art, and the apparatus for introducing titanium dioxide into the furnace tuyere includes a rotary feeding method and a method of discharging the powder of titanium dioxide from the storage tank B1. Securitization and the like.

The rotary feeding method is a method of discharging the powder stored in the storage tank (B1) according to the number of revolutions of the rotary valve, the rotary feeding method as described above is a rotary valve when using a particle having a large particle size, such as titanium spectroscopy Is easily worn and there is a problem that can not be used for a long time.

The fluidization method is divided into two types. The first method is a method of discharging the powder by blowing a high-pressure gas (Gas) into the storage tank (B1) in which the powder is stored.

The above method has a problem in that it is difficult to quantitatively control the discharge amount only by adjusting the fluidization pressure when using a spectroscopic stone having a high specific gravity, and an instant clogging phenomenon occurs in a narrow pipe diameter in the discharge pipe under the storage tank B1. In some cases, the blowing may be interrupted.

The second method, as shown in FIG. 1, uses the motor B3 to control the opening degree of the chuck B2, and the narrow passage of the chuck B2 has a high specific gravity of titanium dioxide TiO2. The wear and tear caused by the spectroscopy, even when the three chucks B2 are used, clogging frequently occurs, and the chucks B2 are often stuck to the chucks B2, making adjustment of the chucks B2 difficult.

It is an object of the present invention to provide an apparatus for reducing refractory wear of a furnace by controlling the amount of titanium dioxide spectroscopy to be effectively injected into the furnace tufts continuously without clogging.

The present invention devised in order to achieve the above object, in the apparatus for injecting spectroscopic stones into the furnace tuyere; An air branch unit for inputting air, storing the air at a proper pressure, and performing a regulator to output a charging air and a blown air, respectively; A hopper unit for storing only the spectroscopic stones having a predetermined size or less and passing the same, so as not to pass and not accumulate in one place; A tank unit configured to uniformly disperse the spectral stones inputted from the hopper unit and accumulate and accumulate the spectral stones by charging air supplied from the air branch unit and maintaining the pressure state when the spectral stones are stored in a constant weight; A mixing unit for introducing and dispersing the spectroscopic stones stored in the tank unit by the reduced rotational force of the tank and mixing the air with the air; And a blowing unit for mixing the spectroscopic stones supplied from the mixing unit with the blowing air again and feeding the blowing holes.

Hereinafter, by the present invention will be described with reference to the accompanying drawings, the titanium dioxide input device of the furnace tuyere.

Attached to explain the present invention, Figure 2 is a functional configuration diagram of the titanium dioxide input device of the furnace tuyere according to the present invention, Figure 3 is a detailed functional configuration of the hopper section, tank section, mixing section, blowing section according to the present invention 4 is a detailed configuration diagram of the mixing section and the blowing section of the present invention, Figure 5 is a detailed configuration diagram of the screw for quantitatively discharging the spectroscopy of the present invention, Figure 6 FIG. 7 is a diagram illustrating a process of mixing ore with air, and FIG. 7 is a diagram illustrating a state of rotation of spectroscopy in the mixing unit according to the present invention, and FIG.

According to the present invention with reference to the attached Figures 2 to 5, the titanium dioxide input device of the furnace tuyere description, in the apparatus for injecting titanium dioxide (TiO2) spectroscopy into the furnace (F6) or the tuyere of the blast furnace ,

Main air (A1) which controls the supply and shutoff of air from the outside by inputting air and storing it in the state of proper pressure and outputting it by charging air and blown air respectively. ); Branch cylinder (A4) for accumulating a predetermined amount of air flowing through the main valve (A1); A pressure gauge (A2) provided at one side of the branch cylinder (A4) to measure whether the accumulated air has reached a predetermined pressure; An air branch unit 100 connected to the branch cylinders A4 and including a charging line and a blowing line for outputting air accumulated in the branch cylinders at a predetermined constant pressure;

By passing only the titanium dioxide (TiO 2) spectroscopy 10 having a predetermined size or less and storing it so as not to pass and not accumulate in one place, the titanium dioxide (TiO 2) spectroscopy 10 introduced from the outside is disturbed. Charging hopper of the inverted triangle shape to collect in one place (H1); 5 mesh screens (H1-1) for filtering and passing only titanium dioxide spectroscopy 10, which is provided at an intermediate portion of the charging hopper H1, by a predetermined size or less; Hopper vibrator fixedly attached to one end of the charging hopper (H1) and applying vibration to the charging hopper (H1) in order not to accumulate and accumulate the titanium dioxide spectroscopy 10 on the mesh screen (H1-1) ( H2-1); A hopper section including a hopper valve H2 that passes through the mesh screen H1-1 and discharges the titanium dioxide spectroscopy 10 collected in the charging hopper H1 to the tank 300 which will be described later. 200),

When the titanium dioxide spectroscopy 10 is evenly distributed and accumulated and the titanium dioxide spectroscopy 10 is stored at a constant weight, the pressure input from the air branch unit 100 is accumulated. Storage tank (H3) for storing the titanium dioxide spectroscopy (10) introduced from the hopper 200 by a certain amount by charging with air and maintaining the pressure state; A tank vibrator (H3-3) provided at a lower side of the storage tank (H3) and periodically applying vibration to the storage tank (H3) so that the incoming titanium dioxide spectroscopy (10) accumulates in the lower portion. ; A load cell guide (H4) for measuring the total weight of the titanium dioxide spectroscopy (10) stored in the storage tank (H3); A load cell (H5) measuring the total weight of the titanium dioxide spectroscopy (10) stored in the storage tank (H3) by the load cell guide (H4); When the titanium dioxide spectroscopy 10 having a predetermined weight is stored in the storage tank H3, a predetermined pressure is supplied by supplying a charge air flowing from the air branch unit 100 to the storage tank H3 by the corresponding control. A charge valve H3-2 to charge until it reaches A fluidizing air unit H3 which continuously supplies air to the storage tank H3 in order to maintain a state in which a predetermined pressure is charged to the storage tank H3 by the charging valve H3-2. -4); A tank part 300 provided at one side of the storage tank H3 and including a tank pressure gauge H6 for measuring the air pressure of the storage tank H3;

By dispersing and dispersing the titanium dioxide spectroscopy 10 stored in the tank unit 300 by the rotational force of the reduced motor, the mixture is discharged from the tank unit 300 and discharged from the tank unit 300. A mixing tube (F2) for receiving the prepared titanium dioxide (TiO 2) spectroscopy 10; Titanium dioxide (TiO 2) spectroscopy (10) stored in the tank portion 300 is to be continuously discharged to the mixing tube in a constant amount, the upper portion of the large diameter and the lower portion of the disk shape of the small diameter is continuously connected to the screw (11) ; A mixing air valve (F1) for supplying air (Air) mixed with the titanium dioxide spectroscopy 10 introduced into the mixing pipe (F2); It is attached to the shaft for driving the screw 11 in two stages of four and supplied from the titanium dioxide spectroscopy 10 and the mixing air valve F1 introduced into the mixing pipe (F2) by the screw (11) A plurality of mixing rods F2-1 for mixing Air twice; A screw motor (F4) for generating a rotational power for driving the screw (11); A mixing unit 400 including a reducer F4-1 for reducing the rotational power generated from the screw motor F4 at a predetermined ratio;

Titanium dioxide spectroscopy 10 discharged from the mixing section 400 by mixing the titanium dioxide spectroscopy 10 supplied from the mixing section 400 with the blown air again and inputting it to the tuyere of the blast furnace F6. Feeding line (F3-1) for supplying; A feeding valve F3 for controlling the discharge of the titanium dioxide spectroscopy 10 supplied from the feeding line F3-1; It comprises a pickup (F3-2) for mixing and discharging the titanium dioxide spectroscopy (10) supplied from the feeding line (F3-1) and the blowing air supplied through the blowing line of the air branch unit 100. It is a structure which consists of the blowing part 500.

Hereinafter, the titanium dioxide input device of the furnace tuyere according to the present invention having the above configuration will be described in detail with reference to FIGS.

According to the present invention, a device for injecting titanium dioxide (TiO2) into a tuyere that blows hot air at a high temperature and high pressure into a blast furnace or blast furnace (F6), wherein air introduced from the outside is introduced through the air main valve A1. Or the inflow is blocked, the air flowing through the air main valve (A1) is stored in the branch cylinder (A4) in the accumulated state.

The air stored in the branch cylinder A4 in the accumulated state is confirmed by the pressure gauge A2 to be a predetermined pressure, and the foreign matter such as water is discharged to the drain valve A3.

A charging line and a blowing line are attached to the branch cylinder A4, respectively, and the pressure reducing line is used to reduce the pressure at an appropriate pressure by the charging regulator P2 and the blowing line by the blowing regulator A5.

The charge air and the blow air flowing in the above charge line and blowing line are supplied or cut off by the respective solenoid valves P3 and A6, and the pressure of the air supplied by the respective pressure gauges P4 and A7. The check valves and the blow-in lines as described above are attached with check valves to prevent air from flowing back from the blast furnace F6 to the branch cylinder A4 by the high-temperature, high-pressure gas Gas.

When the pressure air supplied through the pressure line is charged in the storage tank H3, the titanium dioxide spectroscopy stored in the storage tank H3 is caused by the operation of the mixing air valve F1 and the screw motor F4. 10 is dropped into the mixing pipe (F2), mixed with the mixing (Mixing) air introduced from the mixing air valve (F1) is a structure that is blown into the air vent of the blast furnace (F6), the blowing line There is a flow meter as taken in photograph 1 between the pressure gauge A7 and the injection secondary valve A9 at the blow.

Referring to FIG. 3, the titanium dioxide (TiO 2) spectroscopy 10 is stored in the storage tank H 3, and the charge valve H 3-2 is opened and charged, and blown into the air vent of the furnace F 6. As shown in the figure, the charging hopper H1 has an inverted triangular structure, and a 5 mesh screen H1-1 is provided at the center, and the mass is large by the mesh screen H1-1. Titanium dioxide spectroscopy (10) is not passed or filtered and is filtered, the hopper vibrator (H2-1) is to prevent the spectral stones (10) accumulated and accumulated in the mesh screen (H1-1) does not occur Is activated.

Titanium dioxide (TiO 2) spectroscopy 10 stored in the storage tank (H3) is lowered to the bottom by the periodic operation of the tank vibrator (H3-3), titanium dioxide (TiO 2) spectroscopy 10 stacked below The weight is checked or detected by the load cell guide H4 and the load cell H5, and charging is started when a predetermined weight is detected.

The above charging is completed, and during blown into the tuyeres of the furnace F6 by the action of the mixing unit 400, through the plunging air unit H3-4 in order to maintain or hold the pressure for blowing. Fluidizing air continues to flow into the storage tank H3.

The storage tank (H3) can check the air pressure inside the tank (H6), the lower portion of the storage tank (H3) has a mixing pipe (F2), where the titanium dioxide spectroscopy (10) Due to the opening of the mixing air valve (F1) and the supplied air is mixed while falling structure.

When the above-mentioned titanium dioxide spectroscopy 10 starts blowing into the tuyeres of the furnace F6, a feeding valve F3 is opened, and a quantitative and large amount of titanium dioxide spectroscopy 10 is picked up. -up) (F3-2) is once again mixed with blown air and blown into the above air vents, the attached picture 2 shows the actual structure of the bottom of the mixing tube (F2) and the bottom of the mixing tube (F2) It shows that the screw motor F4 is provided for operation.

Referring to FIG. 4, the titanium dioxide spectroscopy 10 is lowered by a screw 11, and the screw 11 has a lower upper portion of the titanium dioxide spectroscopy 10 in a wider form. Mixing rod (F2-1) attached to the lower part of the screw (11) is attached to the upper and lower double, so that the rotational output of the screw motor (F4) by the reducer (F4-1) at a predetermined ratio The titanium dioxide spectroscopy 10 is dispersed twice or mixed with air by rotating the mixing rod F2-1 simultaneously with the screw 11 by a controlled rotational force.

With the above dispersion, the mixing air valve F1 and the feeding valve F3 of the feeding line F3-1 are opened to reach the pickup F3-2.

The screw 11 is supplied with the rotational force of the decelerated state by the screw motor (F4) and the reducer (F4-1).

Referring to FIG. 5, the interlocking structure of the storage tank H3 and the lower mixing tube F2 is shown in detail, and the screw 11 is connected to the storage tank H3 and the mixing tube F2. It extends vertically, and eight lower mixing rods F2-1 are attached in two layers.                     

The mixing pipe (F2) is provided with a sealing tube 16 of the flange type between the storage tank (H3), the sealing tube 16 and the upper storage tank (H3) of the bolt (14) Is fastened to.

Inside the sealing tube 16 is provided with two layers of round cylindrical packing 12, the inner concave portion and the outer convex portion are assembled with each other, the outer plate fixing bolt 13 by the connecting plate 15 ), The connecting plate 15 is once again fixed to the sealing tube 16 and the lower mixing tube (F2), the sealing tube 16 and the mixing tube (F2) by the connecting bolt 14 Are assembled.

6 and 7 show that the dropped titanium dioxide (TiO 2) spectroscopy 10 is dispersed in the first collision in the mixing rod F2-1, and the inside of the mixing tube F2 is from top to bottom. Furnace and from the top to the bottom of the rotary projection (F2-2) shows the strong rotary fall of the titanium dioxide spectroscopy 10 when the mixing air flows into the four mixing pipes.

The strong falling drop as described above increases the moving speed of the titanium dioxide spectroscopy 10 and is capable of a large amount of blowing into the tuyere, so that there is no blockage.

To more briefly describe the operation of the structure as described above, the present invention blocks the pulverized coal while the furnace (F6) in operation (Cut) and titanium dioxide (TiO2) spectroscopy (10) into the furnace (F6) or blast furnace through Lance It is to improve the method which was blocked frequently and was not able to be blown a lot.

In order to prevent the titanium dioxide (TiO 2) spectroscopy 10 from being cut and to be continuously blown into the tuyere, more than 4 kg / cm ^{2 which} is the internal pressure of the furnace or blast furnace F6. A much higher pressure of 7 to 13 kg / cm ² should be used to prevent clogging during blowing of the titanium dioxide (TiO 2) spectrometer 10 and to allow a large amount of blowing.

Preventing the clogging is to increase the moving speed by increasing the air mixing ratio to the titanium dioxide (TiO2) spectroscopy (10) using a high-pressure air and the mixing tube (F2), the rotating projection in the mixing tube (F2) By making the Titanium Dioxide (TiO 2) to increase the speed of the spectroscopy 10 more strongly.

In addition, in the case of increasing the blowing amount of the titanium dioxide (TiO2) spectroscopy 10, it is possible to adjust the blowing amount by increasing the rotational speed of the screw motor (F4), the initial operation is to operate the screw motor (F4) at low speed After reducing the starting load, the speed is gradually increased to operate, and the amount of blowing of the titanium dioxide (TiO 2) spectroscopy 10 can be confirmed by the weight detection by the load cell (H5) of the storage tank (H3). When the weight or weight of the titanium dioxide (TiO2) spectroscopy (10) of the storage tank (H3) is checked and the weight of the titanium dioxide (TiO2) spectroscopy (10) becomes '0', the stored titanium dioxide (TiO2) powder It is confirmed that all ores 10 have been blown up.

If the weight of the titanium dioxide (TiO2) spectroscopy 10 stored in the storage tank (H3) does not fall to '0', since the blowing is not completed, it should be solved immediately in case of long delay and the method is as follows. Same as

First, the mixing air pressure increase is confirmed on the mixing air valve F1 side, and the injection air flow increase is performed and confirmed through the intake regulator A5 and the flow meter A8.

Secondly, by increasing the speed of the screw motor (F4) and operating the tank vibrator (H3-3) of the storage tank (H3) blows all remaining unincorporated titanium dioxide (TiO2) spectroscopy (10), the blowing is completed Then, when blowing again, it enters into the charging operation of the titanium dioxide (TiO2) spectroscopy 10 like the flowchart shown in FIG.

When the above titanium dioxide (TiO2) spectroscopy 10 is charged, all valves are closed and the vent valve of the storage tank H3 is opened to open the pressure of the storage tank H3. By removing the, and opening the hopper valve (H2) for charging (Open) charge of the titanium dioxide (TiO2) spectroscopy 10 is made.

When the weight of the titanium dioxide (TiO 2) spectroscopy 10 reaches a predetermined value, the vent valve and the storage hopper valve H 2 of the storage tank H 3 are closed to close the charge solenoid valve. The charging is performed by the operation of (P3), and the blowing operation of the titanium dioxide (TiO 2) spectroscopy 10 proceeds, and the method and procedure are illustrated in detail in FIG. 8.

The present invention having the above configuration has the effect of facilitating the quantitative discharge of titanium dioxide (TiO 2) spectroscopy from the storage tank by using a high pressure air, a mixing tube, a mixing protrusion, a screw motor, and a screw.

In addition, since a large amount of titanium dioxide (TiO 2) spectroscopy can be blown without clogging, there is an effect of effectively controlling the amount of blown into the furnace air vent.

Claims (6)

In the apparatus for injecting spectroscopic stones into the furnace tuyere, An air branch unit which inputs air, stores it at a proper pressure, and regulates it and outputs it to a charging air and a blown air respectively; A hopper part for storing only the spectroscopic stones of a predetermined size or less and passing it and not storing it and not accumulating in one place; A tank unit configured to accumulate and evenly distribute the spectroscopic stones inputted from the hopper unit and to accumulate the spectroscopic stones by charging the compressed air inputted from the air branch unit and maintaining the pressure-pressed state; A mixing unit for introducing and dispersing the spectroscopic stones stored in the tank unit by the decelerating rotational force and mixing and discharging the air with air; The apparatus for injecting titanium dioxide into the furnace tufts comprising a blower which mixes the spectroscopic stones supplied from the mixing section with the blown air again and injects them into the tuyere. The method of claim 1, wherein the air branch, A main valve that controls the supply and blocking of incoming air, Branch passage for accumulating a predetermined amount of air flowing through the main valve, A pressure gauge provided on one side of the branch cylinder and measuring whether the accumulated air has reached a predetermined pressure; Titanium dioxide input device of the furnace tuyere characterized in that it comprises a charging line and a blow-in line, respectively connected to the branch cylinder and outputs the air accumulated in the branch at a controlled constant pressure. The method of claim 1, wherein the hopper portion, A charging hopper which collects the injected spectroscopy in one place without disturbing it, A mesh screen for filtering the spectroscopic stones, which are provided at an intermediate portion of the charging hopper, by passing only a predetermined size or less; A hopper vibrator fixedly attached to one end of the charging hopper and applying vibration to the charging hopper so as not to accumulate spectroscopic stones on the mesh screen; And a hopper valve configured to pass through the mesh screen and discharge spectroscopic stones collected in the charging hopper to the tank unit. The method of claim 1, wherein the tank unit, A storage tank for storing the spectroscopic stones introduced from the hopper in a predetermined amount; A tank vibrator provided at a lower side of the storage tank and periodically applying vibration to the storage tank so that the incoming spectroscopic stones are accumulated at a lower portion thereof; A load cell guide for measuring the total weight of the spectroscopic stones stored in the storage tank; A load cell measuring the total weight of the spectroscopic stones stored in the storage tank by the load cell guide; When the spectroscopic stone of a predetermined weight is stored in the storage tank, a pressure reducing valve for supplying a pressure air flowing from the air branch unit to the storage tank under a corresponding control and charging until it reaches a predetermined pressure; A plunging air unit for continuously supplying air to the storage tank to maintain a state in which the predetermined pressure is charged to the storage tank by the charging valve; Titanium dioxide input device of the furnace tuyere characterized in that it comprises a tank pressure gauge provided on one side of the storage tank to measure the air pressure of the storage tank. The method of claim 1, wherein the mixing unit, A mixing tube receiving the spectroscopic stones discharged from the tank unit, The spectroscopy stored in the tank portion is continuously discharged to the mixing tube in a constant amount, the upper portion of the large diameter and the lower portion of the diameter of the disk is connected to the continuous screw, A mixing air valve for supplying air mixed with the spectroscopic stones introduced into the mixing pipe; A plurality of mixing rods attached to the shaft for driving the screw in two stages and mixing the spectroscopy introduced into the mixing tube by the screw and the air supplied from the mixing air valve twice; A screw motor for generating a rotational power for driving the screw; Titanium dioxide input device of the furnace tuyere characterized in that it comprises a reducer for reducing the rotational power generated from the screw motor at a predetermined ratio. The method of claim 1, wherein the blowing unit, A feeding line for supplying the spectroscopic stones discharged from the mixing unit; A feeding valve for controlling the discharge of the spectroscopic stones supplied from the feeding line; And a pickup for mixing and discharging the spectroscopy supplied from the feeding line and the blown air supplied from the air branch unit.

Images