KR101671139B1 - Facility for injecting oxygen from blast furnace tuyere and blast furnace operating method - Google Patents

Abstract

In the facility for blowing pulverized coal and oxygen through the lance into the blast furnace from the blast port, it is possible to prevent the gas in the blast furnace from being mixed into the oxygen piping connected to the lance, or the gas and the oxygen in the blast furnace being mixed into the nitrogen piping.
The oxygen introducing apparatus 100 includes a lance 4, an oxygen pipe 7 provided with an oxygen shut-off valve 22, a flow rate regulating valve 21, a nitrogen pipe 8 provided with a nitrogen shut- And a control device 30 for controlling opening and closing of the oxygen shut-off valve 22 and the nitrogen shut-off valve 28. The oxygen piping 7 is connected to the lance 4 to supply oxygen 40 to the lance 4. The nitrogen piping 8 is connected to the oxygen piping 7 upstream of the oxygen flow rate adjusting valve 21 in the oxygen flow. The oxygen shutoff valve 22 is provided in the oxygen piping 7 upstream of the connecting position of the oxygen piping 7 and the nitrogen piping 8 in the oxygen flow. The control device 30 sets the nitrogen shutoff valve 28 closed when the oxygen shutoff valve 22 is open and opens the nitrogen shutoff valve 28 when the oxygen shutoff valve 22 is closed .

Description

FIELD OF THE INVENTION The present invention relates to an apparatus for blowing oxygen from a blast furnace and a method for operating the blast furnace,

The present invention relates to a facility for blowing pulverized coal from a blast furnace blast hole into a blast furnace and blowing oxygen from a blast furnace blast furnace having a lance capable of blowing oxygen from the vicinity of a blowing position of the pulverized coal, and a blast furnace operating method.

Nowadays, global warming due to increase of carbon dioxide emission is a problem, and suppression of CO ₂ emissions is an important task in steel industry. Therefore, in the recent blast furnace operation, a low reduction ratio raw material operation (also referred to as a low RAR operation) in which a reducing material is blown from a blast furnace tuyeres, RAR is abbreviation of "Reducing Agent Ratio" Which means the operation of reducing the total amount of coke charged from the intake reducing material and the furnace top from the blast furnace tuyere) is strongly promoted. As the reducing material blown from the blast port, fine coal is mainly used. In order to improve the combustibility of the pulverized coal blown into the blast furnace from the blast furnace to reduce the reduction cost, it is considered to blow oxygen from the lance blowing the pulverized coal near the blowing position of the pulverized coal.

On the other hand, in steelworks, a gas such as a fuel-based gas such as a blast furnace gas and a coke oven gas generated in a steel mill, or a combustion enhancing gas, that is, an inert gas such as oxygen or nitrogen, , And piping facilities. In this case, basically, one pipeline is designed to flow one gas, and a place where mixing with a different gas is generated is limited to facilities such as a combustion burner and a gas mixing facility. This is because considering that the connection of the pipings of the different kinds of gas is carried out at all times, another gas is mixed into the one piping, and as a result, troubles such as abnormal combustion in the piping, It is because. Therefore, the mixing of two or more gases into one piping should be avoided. For example, when the supply of oxygen to the pipe for supplying oxygen to the lance is stopped, there is a risk of abnormal combustion if the gas in the furnace flows into the oxygen pipe after stopping the supply of oxygen. Therefore, after stopping supply of oxygen to the oxygen pipe, it is necessary to purge the oxygen pipe with an inert gas such as nitrogen (replace with an inert gas).

As a method of replacing the gas in the pipe, a pipe of an inert gas such as nitrogen is connected to a pipe to be replaced, and an inert gas is supplied, and it is confirmed that the gas concentration in the pipe is in a range that does not cause abnormal combustion, There is a method of supplying a new type of gas, for example, air into the piping, in order to establish a working environment in the piping. In this method, considering the working efficiency, it is preferable that the inside of the pipe is gas-substituted safely and in a short time. As such a gas replacement method, there is a method of forming a region having a high inert gas concentration locally in a pipe and replacing it by supplying air so as not to come into contact with the gas remaining in the pipe, as disclosed in Patent Document 1 . Further, as described in Patent Document 2, in order to prevent abnormal combustion of the gas in the pipe, a gas holder is installed in the middle of the pipe leading to the gas use place, and until the gas directed to the gas use place is blocked , There is a method of temporarily storing the gas in the gas holder so that the gas does not flow to the downstream side.

In any of the above methods, the gas is replaced. In this case, it is well known that a shutoff valve is provided at the most downstream side (connection end side) of a pipe to be connected. The opening and closing operation of the shut-off valve is controlled on the basis of the state information such as the pressure and the flow rate of the gas flowing in the piping of the inlet pipe. As disclosed in, for example, Patent Document 3 and Patent Document 4, a purge nitrogen pipe is connected to a pipe through which a fuel gas flows, and a shutoff valve and a flow rate regulating valve are connected to the nitrogen pipe Thereby controlling the shut-off valve and the flow rate adjusting valve.

Patent Document 1: Japanese Patent No. 4781032 Patent Document 2: Japanese Patent Application Laid-Open No. 2011-6576 Patent Document 3: Japanese Patent Publication No. 50-40085 Patent Document 4: Japanese Patent No. 4744349

However, in the gas replacement method described in Patent Document 1 or Patent Document 2, gas replacement is performed in a state in which the supply of gas is stopped by one shutoff valve. Therefore, due to a power failure or a large earthquake, In the case of failure, the gas replacement operation may be hindered. For example, when the supply of pulverized coal and oxygen is supplied from the lance to the blast furnace blast hole as described above, when the supply of oxygen to the oxygen blast pipe stops, it is first necessary to purge the oxygen blast pipe with an inert gas such as nitrogen If the inert gas shutoff valve is not opened due to the failure of the valve power source and inert gas can not be sent to the oxygen piping, there is a possibility that the gas in the blast furnace is mixed into the oxygen piping to cause abnormal combustion. Particularly in the blast furnace operation in which pulverized coal and oxygen are blown into the blast furnace from the blast furnace using a lance, it is necessary to remove oxygen by replacing the oxygen remaining in the oxygen pipe with an inert gas such as nitrogen have. This is because the blast furnace gas containing CO in the oxygen pipe backflows and reacts with the remaining oxygen to cause abnormal combustion.

In the methods described in Patent Documents 3 and 4, the valve structure of the purge nitrogen pipe, which is always connected to the pipe of the fuel system gas, is composed of one flow rate adjusting valve and one blocking And when the failure or breakage of the shutoff valve occurs for some reason and when the pressure in the pipe of the fuel system gas is always higher than the pressure in the pipe of the purge nitrogen, There is a possibility that abnormal combustion may occur if the air on the side of the nitrogen piping is replaced for maintenance, for example, in this state. That is, in a facility for blowing pulverized coal into a blast hole at a blast hole and blowing oxygen from the lance in the same manner near the blowing position, a pipe for purging nitrogen is always connected to the oxygen pipe and nitrogen flow There is a possibility that a trouble may occur that gas in the blast furnace is mixed into the oxygen pipe or gas and oxygen are mixed into the blast furnace in the nitrogen pipe.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problems, and it is an object of the present invention to provide a method for blowing pulverized coal from a lance and blowing oxygen from a lance in the vicinity of the blowing position, It is an object of the present invention to provide a facility for blowing oxygen into a blast furnace from blast furnace blast openings that can reliably prevent blast furnace gas from being mixed into the oxygen blast pipe, . In addition, the apparatus for blowing oxygen into the blast furnace from the blast furnace tuyere according to the present invention and the blast furnace operating method are useful in the operation of blowing pulverized coal and oxygen with a lance, even when the valve power source is failed, And the like.

The gist of the present invention to solve the above problems is as follows.

(1) A lance capable of blowing pulverized coal and oxygen from a blast furnace tuyere into a blast furnace, an oxygen pipe connected to the lance for supplying oxygen to the lance, a flow rate adjusting valve provided in the oxygen pipe, An oxygen shut-off valve installed in the oxygen piping upstream of a connection position of the oxygen piping and the nitrogen piping, and an oxygen shut-off valve connected to the oxygen shut-off valve and the nitrogen shut- And a control device for controlling the opening and closing of the valve, wherein the control device closes the nitrogen shut-off valve when the oxygen shut-off valve is open, and opens the nitrogen shut-off valve when the oxygen shut- And a device for blowing oxygen from the tuyeres.

(2) a lance capable of blowing pulverized coal and oxygen from the blast hole into the blast furnace, an oxygen pipe connected to the lance for supplying oxygen to the lance, a flow rate adjusting valve provided in the oxygen pipe, And two oxygen shut-off valves provided in the oxygen piping upstream of a connecting position of the oxygen piping and the nitrogen piping, and a second oxygen shut-off valve provided in the oxygen piping between the two oxygen shut- An apparatus for blowing oxygen from a blast furnace outlet having an installed oxygen discharge valve.

(3) The nitrogen piping according to (2), wherein the nitrogen piping includes a check valve, two nitrogen shut-off valves disposed upstream of the check valve, and a nitrogen shut-off valve disposed between the two nitrogen shut- Equipment to blow oxygen from the tuyeres.

(4) A control device for controlling opening and closing of the two oxygen shut-off valves and the two nitrogen shut-off valves, wherein the control device controls the two nitrogen shut-off valves Wherein the two nitrogen shut-off valves are opened when the two oxygen shut-off valves are closed and the two nitrogen shut-off valves are opened when the two oxygen shut-off valves are closed.

(5) a lance capable of blowing pulverized coal and oxygen from the blast hole into the blast furnace, an oxygen pipe connected to the lance for supplying oxygen to the lance, a flow rate adjusting valve provided in the oxygen pipe, A nitrogen pipe connected to the oxygen pipe upstream of the oxygen pipe and upstream of the connection position of the oxygen pipe and the nitrogen pipe and provided in the oxygen pipe when the power source is defective, And an oxygen flow cutoff mechanism for shutting off oxygen.

(6) The nitrogen piping according to the above (5), wherein the nitrogen piping includes a check valve and a nitrogen flow opening / closing mechanism disposed upstream of the check valve and allowing nitrogen flow in the nitrogen piping when the power source is broken. Equipment to blow oxygen from the tuyeres.

(7) The nitrogen flow opening and closing mechanism may include two nitrogen shut-off valves that open when the power source is broken, and a nitrogen shut-off valve that is disposed between the two nitrogen shut-off valves and closes when the power source is broken (6). The facility for blowing oxygen from the blast furnace outlet described in (6).

(8) The oxygen flow cut-off mechanism includes two oxygen shut-off valves that are closed when the power source is in failure, and an oxygen shut-off valve that is provided between the two oxygen shut-off valves in the oxygen line, An apparatus for blowing oxygen from a blast blowing port according to any one of (5) to (7) above, which has an oxygen-dissipating valve.

(9) A receiver tank connected to the nitrogen pipe upstream of the nitrogen shut-off valve or the nitrogen flow opening / closing mechanism, the receiver tank having a volume three to five times as large as the pipe volume from the receiver tank to the blast- (1), (3), (4), and (6) to (8), wherein the nitrogen main pipe shut-off valve is disposed upstream of the receiver tank and closes when the power source is broken In which the oxygen is blown from the blast hole.

(10) A blast furnace operating method for blowing pulverized coal and oxygen into a blast furnace by using a facility for blowing oxygen from a blast furnace tuyere described in any one of (1) to (9) above.

According to the facility for blowing oxygen from the blast furnace outlet of the present invention and the blast furnace operation method, only the nitrogen is supplied downstream from the connection position of the nitrogen pipe and the oxygen pipe, the oxygen pipe can be purged with nitrogen, It is possible to reliably prevent the gas in the blast furnace from being mixed into the oxygen piping even when the valve power source is broken.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a longitudinal sectional view showing one embodiment of a blast furnace to which a blast furnace operating method of the present invention is applied.
2 is a schematic view showing a facility for blowing oxygen into a blast furnace from a blast furnace blast hole shown in Fig. 1;
3 is a sequence explanatory diagram of the control device of Fig. 2; Fig.
4 is an explanatory diagram of a valve operation state at the time of a power source failure by the oxygen inlet equipment of FIG. 2;
5 is a sequence explanatory diagram at the time of failure of the power source by the oxygen blowing facility of FIG. 2;

Next, an embodiment of a blast furnace operating method of the present invention will be described with reference to the drawings. 1 is an overall view of a blast furnace to which the blast furnace operating method of the present embodiment is applied. A blow pipe 2 for blowing hot air is connected to each of the blast furnace blowing openings 3 and a blow pipe 2 is connected to the blast pipe 2 And a lance 4 is provided so as to pass therethrough. A space called the raceway 5 is formed in front of the hot air blowing direction of the blast furnace outlet 3 by the hot air supplied from the blow pipe 2 so that the combustion of the carbonaceous material is mainly performed in this space . The pulverized coal that has passed through the blast furnace 4 from the lance 4 and injected into the raceway 5 is combusted with the volatile matter and the fixed carbon together with the coke, A collection of carbon and ash called char is emitted from the raceway as an unburned car.

The fine coal pulverized into the raceway 5 from the blast port 3 is heated by the radiant heat from the flame in the raceway 5 and is further heated by radiation heat, ), And the pyrolysis starts from the point of time when the temperature is raised to 300 ° C or higher. The flame is formed by ignition of the volatile matter, and the combustion temperature reaches 1400-1700 ° C. When pulverized coal and oxygen are blown in parallel from the lance 4, the pulverized coal is contacted with O ₂ and burned, and the pulverized coal is heated and heated by the heat of combustion. Thereby, the pulverized coal starts combustion at a position close to the lance, and the burning rate also increases.

In this embodiment, in order to improve the combustibility of the pulverized coal, lances are used to blow oxygen around the pulverized coal blowing position. The lance (4) has a structure capable of blowing pulverized coal and oxygen into the blast furnace outlet (3). For example, when the lance 4 is a so-called single-tube lance, it is preferable to use two sets of lances for blowing pulverized coal and lance for blowing oxygen and blowing pulverized coal and oxygen into the blast port 3 do. In the case where the lance 4 is a so-called double tube lance in which a small diameter blowing pipe is sandwiched inside a large diameter blowing pipe, for example, pulverized coal is blown from the inside blowing pipe, And oxygen from the gap of the outside blowing pipe. The blowing of the pulverized coal and the oxygen in the double pipe lance may be opposite to each other, but it is preferable to make the oxygen and the pulverized coal close to each other so as to be more easily combusted.

The lance capable of blowing the pulverized coal and oxygen means that the pulverized coal and oxygen preferably flow through different flow paths in the lance tube and the pulverized coal and oxygen are supplied from the lance outlet portion to the blast port portion And a lance capable of blowing pulverized coal and oxygen into the blast furnace. In the present embodiment, two double tube lances are used to blow oxygen around the blowing position of the pulverized coal, respectively. In the present embodiment, oxygen is supplied only from the lance to approach the pulverized coal and oxygen, and oxygen is not enriched as the air. However, it is also possible to hatch oxygen by blowing air if necessary.

In the normal operation of the blast furnace, pulverized coal and oxygen are blown from the lance 4. When the operation is stopped, or when the power supply of the pulverized coal intake facility is stopped due to an accident or the like, the pulverized coal may be stopped to be taken in. In this case, it is necessary to stop the supply of oxygen and quickly remove the remaining oxygen from the oxygen pipe for supplying oxygen to the lance 4, and to replace (purge) with an inert gas such as nitrogen. This is because, simply by stopping the supply of oxygen, the blast furnace gas containing CO flows back to the oxygen pipe and reacts with the oxygen remaining in the oxygen pipe to cause abnormal burning (abnormal stranding). Even if oxygen is allowed to flow in the lance 4 in order to prevent backflow of the blast furnace gas, the metal may be oxidized under high temperature, which is not desirable in view of facility maintenance. Such a situation may occur not only during normal pulverized coal blowing stop operation but also when pulverized coal blowing or oxygen blowing is stopped due to facility trouble. Particularly, when pulverized coal and oxygen are simultaneously supplied to the lance 4, it is necessary to quickly and securely and reliably replace the inside of the oxygen pipe with an inert gas such as nitrogen. In the present embodiment, this substitution is enabled by the following configuration, for example.

Fig. 2 is a schematic view of a facility for blowing pulverized coal and oxygen into a blast furnace from the blast furnace blast port of Fig. 1; An oxygen blowing apparatus 100 is a device for blowing oxygen from a blast furnace tuyere into a lance 4, an oxygen pipe 7 through which oxygen supplied to the lance 4 flows, a nitrogen A nitrogen flow opening and closing mechanism 80 (various valves) provided in a nitrogen pipe 8 and an oxygen flow shutoff mechanism 70 (various valves) provided in an oxygen pipe 7, And a control device (30) for controlling the apparatus. In the present embodiment, the oxygen pipe 7 means a pipe through which oxygen flows, and includes an oxygen main pipe (main pipe) 11, an oxygen collecting header 12, an oxygen pipe 13, (14), a flexible hose (15), and an oxygen connection pipe (16). The nitrogen pipe 8 means a pipe through which nitrogen flows and has a nitrogen main pipe 24, a nitrogen collecting header 25 and a nitrogen pipe branch 26.

In normal operation, oxygen 40 is supplied to the oxygen main pipe 11, and oxygen flows through the oxygen pipe 7 toward the blast furnace outlet 3. In the present embodiment, the direction of the oxygen flow toward the blast furnace outlet 3 in the oxygen pipe 7 is referred to as the downstream direction, and the opposite direction is referred to as the upstream direction. When the oxygen supply is stopped, nitrogen 50 is supplied to the nitrogen main pipe 24 and flows through the nitrogen pipe 8 toward the oxygen pipe 7. In the present embodiment, in the nitrogen pipe 8, the direction of the nitrogen flow toward the oxygen pipe 7 is referred to as a downstream direction, and vice versa is referred to as an upstream direction.

The pulverized coal PC is supplied from the pulverized coal storage hopper (not shown) to the lance 4 together with the high-pressure gas (high pressure N ₂ ), and the pulverized coal flow rate adjusting valve 6 adjusts the amount of pulverized coal. In the blow pipe 2 (see Fig. 1), air is sent from a blower (not shown) to a hot air furnace, and hot air is supplied therefrom. If oxygen is added to the hot air as required, it is performed upstream of the hot air in the air flow.

The high pressure oxygen supply pipe (oxygen main pipe 11) disposed at the uppermost position of the oxygen pipe 7 is connected to the oxygen branch pipe 13 by branching from the oxygen collecting header 12 by the number of the blast furnace outlet 3 The oxygen 40 is supplied from the oxygen main pipe 11 and is distributed to each lance 4 (each of the blast holes 3). For example, when the number of the blast furnace blowing openings 3 is 40, the number of the oxygen branching tubes 13 is 40 in total. In the present embodiment, since two lances 4 are used, each oxygen branch pipe 13 is branched into two oxygen branch pipes 14, and each of the oxygen branch pipes 14 is connected to the oxygen pipe 14 through the flexible hose 15 And is connected to the pipe 16 to supply oxygen to each of the (double) pipe lances 4 from the respective oxygen connecting pipes 16. The oxygen introducing apparatus 100 includes a plurality of lances 4 corresponding to the blast furnace outlet 3 and an oxygen supply pipe (oxygen main pipe 11) for supplying oxygen to the lance 4, A plurality of oxygen branch pipes 13 branched from each blast air outlet 3 and an oxygen flow rate adjusting valve 21 provided in each of the plurality of oxygen branch pipes 13; And a nitrogen pipe 8 connected to each oxygen branch pipe 13 on the upstream side of the valve 21.

The oxygen connection pipe 16 is provided with two connection pipe shutoff valves 17 at the side of the lance 4, that is, at the downstream end of the oxygen connection pipe 16, And a connection pipe dissipating valve 19 is connected between the two connection pipe shutoff valves 17. The connecting pipe check valve 18 is connected to the connecting pipe check valve 18, The branch pipe shutoff valve 20 is disposed on the flexible hose 15 side, that is, on the upstream side end. The oxygen flow branching mechanism 13 is provided with an oxygen flow blocking mechanism 70. The oxygen flow blocking mechanism 70 has a function of shutting off the oxygen flow in the oxygen piping when the power source is defective It is to exert. 2, the oxygen branch pipe 13 is provided with an oxygen flow rate regulating valve 21 on the side of the oxygen branch pipe 14, that is, on the downstream side end, and the oxygen flow rate regulating valve 21 is provided on the upstream side of the oxygen flow rate regulating valve 21 Oxygen shut-off valves 22 are disposed between the two oxygen shut-off valves 22, and an oxygen shut-off valve 23 is connected between the two oxygen shut-off valves 22. The oxygen flow cut-off mechanism 70 includes two oxygen shut-off valves 22, an oxygen shut-off valve 23 and a control device 30. The two oxygen shut-off valves 22, The release valve 23 is an open / close valve that is opened and closed by a power source. When the power source is failed, the two oxygen shutoff valves 22 are closed and the oxygen shutoff valve 23 is opened. The two oxygen shut-off valves 22 are normally closed shut-off valves that are opened by a power source. The oxygen shut-off valves 23 are normally open shut-off valves that are closed by a power source.

A nitrogen pipe 8 is connected to the oxygen inlet facility 100 to purge the inside of the oxygen pipe 14 and the oxygen connecting pipe 16 with nitrogen which is an inert gas. In this nitrogen pipe 8, nitrogen is distributed from the high-pressure nitrogen main pipe 24 through the nitrogen collecting header 25 and the nitrogen pipe branch 26 to the oxygen pipe branch 13. For example, when the number of the blast furnace blowing openings 3 is 40 and the number of the oxygen branching tubes 13 is 40, the number of the nitrogen branching tubes 26 is also 40. Each of the 40 nitrogen-containing branch pipes 26 is connected to the oxygen flow control valve 21 and the oxygen shut-off valve 22 on the downstream side via the nitrogen check valve 27, And is connected to an oxygen branch pipe 13 corresponding to each of them. The nitrogen check valve 27 prevents oxygen from flowing into the nitrogen branch pipe 26 from the oxygen branch pipe 13.

The nitrogen flow branching mechanism 26 is provided with a nitrogen flow opening and closing mechanism 80. The nitrogen flow opening and closing mechanism 80 has a function of flowing nitrogen into the nitrogen piping 8 when the power source is broken will be. 2, two nitrogen shut-off valves 28 are disposed in the nitrogen branch pipe 26 at the side of the nitrogen check valve 27, that is, at the connection side end to the oxygen branch pipe 13, A nitrogen dissipating valve 29 is connected between the nitrogen shut-off valves 28. The nitrogen flow opening and closing mechanism 80 includes two nitrogen shut-off valves 28 and 29 and a control device 30 and includes two nitrogen shut-off valves 28 and a nitrogen shut- (29) is an open / close valve that is opened and closed by a power source. When the power source is broken, the two nitrogen shut-off valves (28) are opened and the nitrogen shut-off valves (29) are closed.

The oxygen inlet facility 100 includes a receiver tank 31 connected to the nitrogen pipe 8 upstream of the nitrogen shutoff valve 28 and a nitrogen main pipe shutoff valve 32 disposed upstream of the receiver tank 31. [ As shown in Fig. 2, the receiver tank 31 is connected to the nitrogen main pipe 24, and the nitrogen main pipe shutoff valve 32 is disposed in the nitrogen main pipe 24. The nitrogen main pipe shut-off valve 32 is a valve that is opened and closed by a power source and is closed when the power source is broken. The receiver tank 31 is filled with nitrogen and the volume of the receiver tank 31 is 3 to 5 times as large as the volume of the pipe from the downstream side to all the blast holes 3.

With this arrangement, when the power source is in operation, nitrogen is supplied to all of the piping from the receiver tank 31 to the blast blowing port 3. The piping from the receiver tank 31 to the blast furnace outlet 3 is a pipe between the lance 4 from the receiver tank 31 to the blast furnace outlet 3 and the oxygen piping 7 and the nitrogen piping 8, . The receiver tank 31 preferably has a pressure gauge PG in addition to the pressure gauge PT and further has facilities such as the safety valve 33 and the drain valve 34. [

The receiver tank 31 may be disposed in the nitrogen branch pipe 26 upstream of the nitrogen shut-off valve 28 in the downstream of the nitrogen header header 25 instead of the configuration shown in Fig. In this case, the volume of the receiver tank 31 may be 3 to 5 times as large as the volume of the piping from the downstream side to one blast furnace outlet 3, but the number of receivers corresponding to the number of blast furnace blast openings 3 The tank 31 is required. In the embodiment shown in Fig. 2, although the volume of the receiver tank 31 is large, it is enough to make one.

The various valves of the oxygen inlet facility 100 are made controllable by the control device 30 in the normal operation while the power is being supplied and in particular the oxygen flow control valve 21, The opening and closing control and the opening degree control are performed by the control device 30 in the same manner as in the first embodiment of the present invention All. In the normal operation of the blast furnace 1, that is, in the ironmaking operation, oxygen must be supplied from the lance 4 together with the fine coal, so oxygen must be supplied to the downstream side of the oxygen tube 14. 3, the two oxygen shut-off valves 22 are opened, the oxygen shut-off valves 23 are closed, the two nitrogen shut-off valves 28 are closed, the nitrogen shut-off valves 29 Is opened, and the opening control of the oxygen flow rate regulating valve 21 is performed as necessary. In this state, no nitrogen is supplied from the nitrogen branch pipe 26 to the oxygen branch pipe 14, and only oxygen is supplied from the oxygen branch pipe 13 to the oxygen branch pipe 14.

When stopping the oxygen supply to the downstream side of the oxygen branch pipe 14 for the reason such as stopping the operation of the blast furnace from this state, as shown in Fig. 3, the two oxygen shutoff valves 22 are closed, oxygen The release valve 23 is opened and the two nitrogen shut-off valves 28 are opened and the nitrogen release valves 29 are closed. In this state, oxygen is not supplied from the oxygen branch pipe 13 to the oxygen branch pipe 14, nitrogen is supplied from the nitrogen branch pipe 26 to the oxygen branch pipe 14, and the oxygen pipe 7 and the nitrogen pipe 8 is purged with nitrogen. At this time, even if the oxygen shut-off valve 22 on the downstream side is not completely closed, for example, oxygen is dissipated from the oxygen shut-off valve 23 and replaced by nitrogen, and oxygen supply to the downstream side is interrupted. In this state, even if the oxygen shut-off valve 23 is not completely opened, the oxygen shut-off valve 23 on the upstream side cuts off the oxygen supply to the downstream side. That is, if two oxygen shut-off valves 22 and oxygen shut-off valves 23 provided in the oxygen piping 7 are provided between the two oxygen shut-off valves 22 in the oxygen inlet facility 100, The oxygen supply to the downstream side can be surely blocked. As a result, it is possible to prevent oxygen from being mixed into the side of the nitrogen branch pipe 26, thereby reducing the possibility of occurrence of troubles due to defects in the valve operation.

When oxygen is supplied to the downstream side of the oxygen branch pipe 14 from the state where the oxygen supply to the downstream side of the oxygen branch tube 14 is stopped, as shown in Fig. 3, again, two oxygen shutoff valves 22 The two nitrogen shut-off valves 28 are closed and the nitrogen shut-off valve 29 is opened and the oxygen shut-off valve 28 is closed if necessary. The oxygen shut-off valve 23 is closed, And performs opening control. Thus, the nitrogen purged downstream of the oxygen branch tube 14 is blown into the blast furnace 3 by the supplied oxygen, and then oxygen is blown from the lance 4.

As described above, in the oxygen inlet facility 100 of the present embodiment, the flow rate regulating valve 21 is provided in the oxygen pipe 7 connected to the lance 4 through which the oxygen supplied to the lance 4 flows, A nitrogen piping 8 is connected to the oxygen piping 7 on the upstream side of the flow rate regulating valve 21 and two oxygen shutoff valves 22 are provided upstream of the connection position of the oxygen piping 7 and the nitrogen piping 8 And an oxygen discharge valve 23 is provided between the two oxygen shut-off valves 22 of the oxygen piping 7. Therefore, when the oxygen of the oxygen pipe 7 downstream of the connection position is purged with nitrogen, for example, when two oxygen shut-off valves 22 are closed and the oxygen shut-off valve 23 is opened , It is possible to supply only nitrogen to the downstream side of the connecting position of the oxygen pipe 7 and the nitrogen pipe 8 and to purge the same, thereby preventing the gas in the blast furnace from being mixed into the oxygen pipe 7.

The nitrogen pipe 8 is provided with a nitrogen check valve 27, two nitrogen shut-off valves 28 disposed on the upstream side of the nitrogen check valve 27 and two nitrogen shut-off valves 28 A nitrogen release valve 29 is provided. Therefore, for example, when oxygen in the oxygen pipe 7 on the downstream side of the connection position is purged with nitrogen, the two oxygen shutoff valves 22 are closed and the oxygen shutoff valve 23 is opened The nitrogen shut-off valve 28 is opened and the nitrogen shut-off valve 29 is closed, only the nitrogen can be supplied to the downstream side of the connection position of the nitrogen piping to purge the oxygen piping 7 It is possible to prevent the gas in the blast furnace from being mixed in the furnace, or the gas and the oxygen in the furnace can be mixed into the nitrogen piping 8. In addition, for example, when oxygen is supplied downstream of the connection position of the nitrogen pipe 8 from a state where nitrogen is purged downstream from the connection position, the two nitrogen shut-off valves 28 are closed The oxygen shut-off valve 22 is opened and the oxygen shut-off valve 23 is closed so that only oxygen is supplied downstream of the connection position of the nitrogen piping 8 And it becomes possible to prevent oxygen from being mixed into the nitrogen pipe 8. As a result,

The controller 30 closes the two nitrogen shut-off valves 28 when the two oxygen shut-off valves 22 are open and closes the two nitrogen shut-off valves 28 when the two oxygen shut- Oxygen can be supplied to the downstream side of the connecting position of the oxygen pipe 7 and the nitrogen pipe 8 or purged with nitrogen by opening the valve 28. At this time, It is possible to prevent the gas from being mixed into the furnace, or the gas and oxygen in the furnace can be mixed into the nitrogen pipe 8. That is, the controller 30 sets at least one nitrogen shut-off valve 28 closed when at least two oxygen shut-off valves 22 are open, and at least one oxygen shut- , If both (two) of the nitrogen shut-off valves 28 are opened, oxygen can be supplied to the downstream side of the connection position or purged with nitrogen.

Next, the oxygen shut-off valve 22, the oxygen shut-off valve 23, the nitrogen shut-off valve 28, the nitrogen shut-off valve 29, and the nitrogen main shut-off valve 32 when the power source is turned off The valve operation is shown in Fig. For example, when the power source of these valves is the compressed air, the control device 30 detects the failure of the valve power source, that is, the compressed air, and when the power source fails, the oxygen shutoff valve 22 is closed, The nitrogen shut-off valve 28 is closed, the nitrogen shut-off valve 29 is closed, and the nitrogen main pipe shut-off valve 32 is closed. On the other hand, when the power source of the valve is the same as the electric power, the control device 30 may become inoperable as the case may be. In such a case, the oxygen shut-off valve 22 is normally closed without a power source, the oxygen shut-off valve 23 is normally open without a power source, the nitrogen shut-off valve 28 is normally open without a power source, Normally closed, the nitrogen main pipe shutoff valve 32 is normally closed without a power source. Therefore, when the valve power source is in a failure state, each valve is opened and closed as shown in FIG.

When the power source is in a failure state, the oxygen flow cut-off mechanism 70 functions to close one of the oxygen shut-off valves 22 on the upstream side, and when the oxygen flow is shut off, It is possible to prevent the gas in the furnace from flowing back into the furnace. When the two oxygen shut-off valves 22 are closed and the oxygen shut-off valves 23 are opened, it is possible to more reliably prevent backflow of the gas in the blast furnace into the upstream piping of the oxygen shut-off valve 22 However, it is possible to prevent oxygen from being mixed into the nitrogen pipe 8.

In addition, the nitrogen flow opening / closing mechanism 80 functions to open the two nitrogen shut-off valves 28 and 28, close the nitrogen shut-off valve 29, close the two oxygen shut-off valves 22 In addition, when the oxygen discharge valve 23 is opened, the downstream side of the connection position of the nitrogen pipe 8 is purged with nitrogen, and it is possible to prevent the gas in the blast furnace from being mixed into the oxygen pipe 7. If two shutoff valves 22 and 28 are provided for each of the oxygen pipe 7 and the nitrogen pipe 8 and the drain valves 23 and 29 are provided therebetween, It is possible to prevent mixing of the gas with one shut-off valve and to dissipate the gas leaked from the shut-off valves 23 and 29. Therefore, even if leakage occurs from one of the shut- It is possible to prevent the gas from being pressurized to the original pressure by filling the space between the shutoff valves, and it is possible to further reduce the possibility that the other gases are mixed with each other.

Fig. 5 shows the operation of each valve when the power source of the valve is broken, and the change in the pressure in the receiver tank 31 with time. For example, when a failure occurs in the power source from the normal operation of blowing pulverized coal and oxygen from the lance 4 as described above, the oxygen shutoff valve 22 is closed, the oxygen shutoff valve 23 is opened, The shutoff valve 28 is opened, the nitrogen discharge valve 29 is closed, and the nitrogen main pipe shutoff valve 32 is closed. Therefore, when the power source fails, the supply of oxygen from the oxygen branch pipe 13 to the oxygen branch pipe 14 is stopped and the supply of nitrogen from the nitrogen branch pipe 26 to the oxygen branch pipe 14 becomes possible . At this time, since the nitrogen main pipe shutoff valve 32 is closed, the supply of nitrogen to the nitrogen main pipe 24 is unlikely, but the nitrogen stored in the receiver tank 31 is supplied to the nitrogen main pipe 24, ), And is supplied to the oxygen branch pipe 14 through the nitrogen branch pipe 26. With this supply, the pressure in the receiver tank 31 gradually decreases.

The capacity in the receiver tank 31 is equal to or higher than the piping volume from the receiver tank 31 to the lance 4 of the blast furnace outlet 3 downstream of the blast furnace 3, It becomes a little much. However, in the case where the valve power source is the same as the electric power, it may be assumed that the blast furnace itself is in a halt state (rest wind) due to the failure of the valve power source. When the blast furnace is in the stop (blow) state, there is a possibility that the pressure in the blast furnace is zero (atmospheric pressure). In this case, since nitrogen from the receiver tank 31 passes through the oxygen branch pipe 13 and the oxygen branch pipe 14 and is blown into the blast furnace 1, the tank capacity is set to 3 to 5 times the pipe volume to be replaced . Since this capacity is determined by the pipe shape such as the possibility of gas accumulation, nitrogen is actually poured from the receiver tank 31 into the lance 4 of the blast furnace outlet 3 at all the blast furnaces and the nitrogen concentration in the pipe and the cumulative flow rate As shown in FIG. By doing so, the downstream side from the connection position of the oxygen piping 7 and the nitrogen piping 8 can be quickly purged with nitrogen even when the valve power source is in failure, whereby the oxygen piping 7 ), And nitrogen can not flow more than necessary. Therefore, excessive cooling of the blast furnace outlet 3 can be prevented.

1 blast furnace
2 blow pipes
3 blast furnace tuyere
4 Lance
5 raceway
6 Pulverized coal flow adjustment valve
7 Oxygen piping
8 Nitrogen piping
11 Oxygen Main Building
12 Oxygen Set Header
13 Oxygen distributor
14 oxygen tube
15 flexible hose
16 oxygen connector
17 Connection pipe shutoff valve
18 connector check valve
19 Connecting pipe Dissolving valve
20 Branch shutoff valve
21 Oxygen flow adjustment valve
22 oxygen shutoff valve
23 oxygen discharge valve
24 Nitrogen Main Building
25 nitrogen set header
26 Nitrogen gasoline engine
27 Nitrogen check valve
28 Nitrogen shutoff valve
29 Nitrogen Release Valve
30 control device
31 receiver tank
32 Nitrogen main pipe shutoff valve
33 Safety valve
34 Drain Valve
40 oxygen
50 nitrogen
70 oxygen flow cutoff mechanism
80 Nitrogen flow opening / closing mechanism
100 Oxygen Filling System

Claims (10)

A lance capable of blowing pulverized coal and oxygen from a blast hole into the blast furnace,
An oxygen pipe connected to the lance for supplying oxygen to the lance,
A flow control valve provided in the oxygen pipe,
A nitrogen pipe connected to the oxygen pipe upstream of the flow rate adjusting valve,
Two oxygen shut-off valves provided in the oxygen piping upstream of a connecting position of the oxygen piping and the nitrogen piping,
And an oxygen discharge valve installed in the oxygen pipe between the two oxygen shutoff valves,
Wherein the nitrogen piping includes a check valve, two nitrogen shut-off valves disposed upstream of the check valve, and a nitrogen shut-off valve disposed between the two nitrogen shut-off valves,
And a control device for controlling opening and closing of the two oxygen shut-off valves and the two nitrogen shut-off valves,
Wherein the control device sets the two nitrogen shut-off valves to be closed when the two oxygen shut-off valves are open, and opens the two nitrogen shut-off valves when the two oxygen shut-off valves are closed, An apparatus for blowing oxygen from a blast-furnace tuyere that opens an oxygen-dissipating valve. A lance capable of blowing pulverized coal and oxygen from a blast hole into the blast furnace,
An oxygen pipe connected to the lance for supplying oxygen to the lance,
A flow control valve provided in the oxygen pipe,
A nitrogen pipe connected to the oxygen pipe upstream of the flow rate adjusting valve,
And an oxygen flow cutoff mechanism installed in the oxygen piping upstream of a connection position of the oxygen piping and the nitrogen piping to shut off the oxygen flow in the oxygen piping when the power source is defective,
Wherein the nitrogen piping comprises a check valve and a nitrogen flow opening and closing mechanism disposed upstream of the check valve and for allowing nitrogen to flow through the nitrogen piping when the power source is broken,
Wherein the nitrogen flow opening and closing mechanism includes two nitrogen shut-off valves that open when the power source is in failure and a nitrogen shut-off valve that is disposed between the two nitrogen shut-off valves and closes when the power source is broken,
The oxygen flow cut-off mechanism includes two oxygen shut-off valves that are closed when the power source is broken, and an oxygen shut-off valve that is provided between the two oxygen shut-off valves in the oxygen line, And a device for blowing oxygen from the tuyeres. The method according to claim 1,
A receiver tank connected to the nitrogen pipe upstream of the nitrogen shut-off valve, the receiver tank having a volume three to five times as large as the pipe volume from the receiver tank to the blast blowing port,
And a nitrogen main pipe shut-off valve which is disposed on an upstream side of the receiver tank and closes when the power source is broken. The method of claim 2,
A receiver tank connected to the nitrogen pipe upstream of the nitrogen flow opening / closing mechanism, the receiver tank having a volume that is three to five times as large as the pipe volume from the receiver tank to the blast-
And a nitrogen main pipe shut-off valve which is disposed on an upstream side of the receiver tank and closes when the power source is broken. A blast furnace operating method for blowing pulverized coal and oxygen into a blast furnace by using a blast furnace blast furnace as set forth in any one of claims 1 to 4 for blowing oxygen. delete delete delete delete delete

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