Blast furnace operation method and lance

Abstract

A method is provided for operating a blast furnace by blowing a solid reducing material, a flammable gaseous reducing material and a combustible gas into a blast furnace from tuyeres through a lance into a blast furnace, wherein a parallel type lance prepared by bundling three independent blowing tubes in parallel and integrally housing them into an outer tube is used, and either one or both of the gaseous reducing material and the combustible gas and the solid reducing material are simultaneously blown through the respective blowing tubes, while the blowing tube for the solid reducing material and the blowing tube for the gaseous reducing material are positioned above the blowing tube for the combustible gas in the blowing through the parallel type lance as well as a lance structure thereof.

Claims

1. A method of operating a blast furnace by blowing a solid reducing material, a gaseous reducing material and a combustible gas into a blast furnace from tuyeres through a lance into a blast furnace, wherein a parallel lance prepared by bundling three independent blowing tubes arranged adjacent to each other and in parallel to each other, and integrally housing the three independent blowing tubes into an outer tube for the lance is used, and either one or both of the gaseous reducing material and the combustible gas are simultaneously blown with the solid reducing material through the respective blowing tubes, wherein the blowing tube for the solid reducing material and the blowing tube for the gaseous reducing material are positioned above the blowing tube for the combustible gas in the blowing through the parallel lance.

2. The method of operating a blast furnace according to claim 1, wherein the blowing tube for solid reducing material, the blowing tube for gaseous reducing material and the blowing tube for combustible gas in the parallel lance are arranged so that an angle of a face passing an outer contact point between a center of the blowing tube for solid reducing material and the outer tube for lance to a radially vertical plane of the lance inserted into a blowpipe is within ?90?.

3. A lance for blowing a solid reducing material, a gaseous reducing material and a combustible gas through tuyeres into a blast furnace in accordance with the method of claim 1, the lance having a structure that three independent blowing tubes are bundled adjacent to each other and in parallel to each other, and the three independent blowing tubes are integrally housed in an outer tube for lance, wherein the blowing tube for the solid reducing material and the blowing tube for the gaseous reducing material are positioned above the blowing tube for the combustible gas.

4. A lance according to claim 3, wherein the blowing tubes are arranged so that an angle of a face passing an outer contact point between a center of the blowing tube for solid reducing material and the outer tube for lance to a radially vertical plane of the lance inserted into a blowpipe is within ?90?.

5. A lance according to claim 3, wherein each of the blowing tubes is a tube having an inner diameter of not less than 6 mm but not more than 30 mm.

6. A lance according to claim 4, wherein each of the blowing tubes is a tube having an inner diameter of not less than 6 mm but not more than 30 mm.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a longitudinal section view illustrating an example of the blast furnace.

(2) FIG. 2 is a view explaining a combustion state when only pulverized coal is blown through a lance.

(3) FIG. 3 is a view explaining a combustion mechanism of pulverized coal.

(4) FIG. 4 is a view explaining a combustion mechanism when LNG and oxygen are blown together with pulverized coal.

(5) FIG. 5 is an explanatory diagram illustrating an arrangement of blowing tubes in a lance (outer tube).

(6) FIG. 6 is a graph showing pressure loss in combustion experiments.

(7) FIG. 7 is a graph showing a lance surface temperature in combustion experiments.

(8) FIG. 8 is an explanatory diagram of an outer diameter in a lance.

(9) FIG. 9 is a schematic view of an apparatus for combustion experiment.

(10) FIG. 10 is a view explaining an arrangement of each blowing tube in a lance.

(11) FIG. 11 is a graph showing a change of combustion temperature in combustion experiments.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION

(12) The blast furnace operation method according to embodiments of the invention and the lance used in this operation will be described with reference to the accompanying drawings below. FIG. 1 is a schematic view of a blast furnace applied to the blast furnace operation method according to an embodiment of the invention. As shown in this figure, the blast furnace 1 is provided with plural tuyeres in its peripheral direction. To the tuyere 3 is connected a blowpipe (blast pipe) 2 for blowing hot air, and the blowpipe 2 is provided with a lance 4 inserted obliquely mainly from above toward a center of an axial direction of the blowpipe. Forward a blowing direction of hot air from the tuyere 3 (inside the furnace) is formed a combustion space called as a raceway 5 being also a coke deposit layer, and reduction of iron ore is mainly performed in the combustion space to produce a molten iron.

(13) FIG. 2 shows a combustion state when only a pulverized coal 6 is blown from the lance 4. The pulverized coal 6 is blown from the lance 4 through the tuyere 3 into the raceway 5 and lumpy coke 7 is charged from the top of the furnace and deposited in the raceway 5, where volatile matter and fixed carbon thereof are combusted. An aggregate of unburned residual carbon and ash, which is generally called as a char, is dispersed from the raceway 5 inside the furnace as an unburned char 8. A blowing rate of hot air forward the blowing direction of hot air blown from the tuyere 3 into the furnace is about 200 m/sec and an O.sub.2 existing region from the front end of the lance 4 into the raceway 5 is about 0.3-0.5 m. Therefore, the heating of pulverized coal particles and the contact efficiency (dispersibility) with oxygen (O.sub.2) as a combustible gas are necessary to be improved substantially in a level of 1/1000 second.

(14) FIG. 3 is an explanatory view of a combustion mechanism when only the pulverized coal (PC) 6 as a solid reducing material is blown from the lance 4 into the blowpipe 2. The particles of the pulverized coal 6 blown from the tuyere 3 into the raceway 5 are heated by radiant heat transfer from the flame in the raceway 5 and further the temperature of the particles is violently raised by radiant heat transfer and conduction transfer. Thermal decomposition is started from a time of heating to not less than 300? C. and volatile matter is ignited to form flame and the combustion temperature (particle temperature) reaches 1400-1700? C. After the volatile matter is discharged, the aforementioned char 8 is formed. Since the char 8 is composed mainly of fixed carbon, carbon dissolving reaction is caused together with the combustion reaction.

(15) FIG. 4 is an explanatory view of a combustion mechanism when LNG as a preferable example of the flammable gaseous reducing material and oxygen as a preferable example of the combustible gas (not shown) are blown together with the pulverized coal 6 from the lance 4 into the blowing pipe 2. This figure is a case of simultaneously blowing the pulverized coal, LNG and oxygen simply. Moreover, a dashed line in the figure shows a combustion (particle) temperature in the blowing of only the pulverized coal shown in FIG. 3 as reference. When the pulverized coal and LNG and oxygen are simultaneously blown as mentioned above, it is considered that the pulverized coal is dispersed associated with the diffusion of gas, and LNG is combusted by the contact with oxygen, and the pulverized coal is rapidly heated by the combustion heat. In this case, therefore, the combustion of the pulverized coal is performed in a position near to the lance. As the position of starting the combustion becomes near to the lance, a chance of damaging the lance becomes higher, so that it is necessary to enhance the durability of the lance or a cooling ability.

(16) FIG. 5a shows a general multiple-tube type lance conventionally used. FIG. 5b shows a parallel type lance proposed in an embodiment of the invention. The multiple-tube type lance is a coaxially triple tube of an inner tube I, a middle tube M and an outer tube O made of stainless steel tube, and dimensions of the respective tubes are shown in the figure. Moreover, a gap between the inner tube I and the middle tube M is 1.15 mm, and a gap between the middle tube M and the outer tube O is 0.65 mm.

(17) In the parallel type lance according to an embodiment of the invention, a blowing tube 21 for solid reducing material, a blowing tube 22 for gaseous reducing material and a blowing tube 23 for combustible gas such as oxygen or the like are bundled in parallel and integrally housed in an outer tube for lance, and the dimensions of the respective tubes are shown in the figure.

(18) In FIG. 6 are shown results of comparative measurement on pressure loss of the multiple-tube type lance and the parallel type lance. As seen from this figure, the pressure loss is less in the parallel type lance as compared to the multiple-tube type lance under the same pathway. This is considered due to the fact that the blowing space (volume in the blowing tube) is made relatively large to decrease airflow resistance in the case of the parallel type lance.

(19) FIG. 7 shows a comparison chart of cooling ability between the lances (multiple-tube type and parallel type). As seen from this figure, the cooling ability under the same pressure loss is higher in the parallel type lance than in the multiple-tube type lance. This is considered due to the fact that the flow rate capable of flowing under the same pressure loss is large because the airflow resistance in the tube is small.

(20) In FIG. 8 is noticed an outer diameter of a lance. FIG. 8a shows an outer diameter of a non-water cooling type lance, and FIG. 8b shows an outer diameter of a water cooling type lance. As seen from this figure, the outer diameter of the lance is small in the parallel type lance as compared to the multiple-tube type lance. This is considered due to the fact that the parallel type lance can decrease the pathway, tube thickness and sectional area of water cooling portion as compared to the multiple-tube type lance.

(21) In order to compare the combustibility between the parallel type lance and the multiple-tube type lance, combustion experiment is performed with an apparatus for combustion experiment shown in FIG. 9. In an experimental furnace 11 are filled lumpy cokes, and an interior of a raceway 15 can be observed through an inspection window. A lance 14 is inserted into a blowpipe (blast pipe) 12, whereby hot air produced by a combustion burner 13 can be blown into the experimental furnace 11 at a given blowing rate. In the blast pipe 12, it is also possible to adjust an oxygen enriched amount during the air blowing. The lance 14 can blow the pulverized coal and either one or both of LNG and oxygen into the blast pipe 12. An exhaust gas produced in the experimental furnace 11 is separated into an exhaust gas and dust by a separating device 16 called as a cyclone, in which the exhaust gas is supplied to an equipment for treating the exhaust gas such as auxiliary combustion furnace or the like, and the dust is collected in a collection box 17.

Combustion Experiment

(22) As a lance 14 are used a single tube lance, a triple tube lance (which is also called as multiple-tube type lance hereinafter) and a parallel type lance prepared by bundling three blowing tubes in parallel and integrally housing them in this combustion experiment. Based on a case that only the pulverized coal is blown through the single tube lance, the pulverized coal is blown through the inner tube and oxygen is blown from a gas between the inner tube and the middle tube and LNG is blown from a gap between the middle tube and the outer tube in the multiple-tube type lance. In the parallel type lance, the pulverized coal, LNG and oxygen are blown through the bundled independent blowing tubes. As to a case that blowing positions are changed around the axis of the lance are measured combustion temperature with a two-color thermometer, pressure loss in the lance, lance surface temperature and outer diameter of a lance. As is well-known, the two-color thermometer is a radiation thermometer for measuring temperature by utilizing heat radiation (movement of electromagnetic wave from high-temperature object to low-temperature object). Noting that wave distribution shifts toward a short wave side as the temperature becomes higher, it is one of wave distribution forms for determining the temperature by measuring the change of temperature in the wave distribution. Especially, radiation energies at two waves are measured for grasping the wave distribution, and the temperature is determined from a ratio thereof.

(23) In this experiment, the pulverized coal (PC) is blown from the blowing tube 21 for solid reducing material and LNG is blown from the blowing tube 22 for gaseous reducing material and oxygen is blown from the blowing tube 23 for combustible gas as shown in FIG. 10. In the case of using a lance prepared by bundling three independent blowing tubes in parallel and integrally housing them into an outer tube for lance, the blowing through the parallel type lance is performed so that the blowing tube for the solid reducing material and the blowing tube for the gaseous reducing material are positioned above the blowing tube for the combustible gas. That is, the position relation of pulverized coal, LNG and oxygen blown into the blowpipe is a relation that oxygen is blown beneath an axial center of the blowpipe and the pulverized coal and LNG are blown above.

(24) Such a position relation means that the blowing through the parallel type lance is performed by such an arrangement of a lance that an an angle of a face passing an outer contact point between a center of the blowing tube for solid reducing material and the lance to a radially vertical plane of the lance inserted into a blowpipe is within ?90? or an arrangement relation of each of the blowing tubes. Namely, when a position corresponding to an outer diameter of the lance on an outer peripheral surface of the blowing tube 21 for pulverized coal is a point A, combustion temperature is measured by the two-color thermometer at a position of 0? that the point A lies in an uppermost part, a position clockwise rotating the point A by 60? around the axial line of the lance and a position rotating the point A by 180?, respectively. Moreover, the insert length of the lance into the blowpipe is 50 mm.

(25) The pulverized coal as a solid reducing material has a fixed carbon (FC) content of 71.3%, a volatile matter (VM) content of 19.6% and an ash content (Ash) of 9.1% and the blowing condition thereof is 50.0 kg/h (corresponding to 158 kg/t as a specific consumption of molten iron). The blowing condition of LNG is 3.6 kg/h (5.0 Nm.sup.3/h, corresponding to 11 kg/t as a specific consumption of molten iron). The coke is used to satisfy .sup.150.sub.15D183 by a test method described in JIS K2151. Blast condition is that a blast temperature of 1100? C., a flow amount of 350 Nm.sup.3/h, a flow rate of 80 m/s and O.sub.2 enrichment+3.7 (oxygen concentration: 24.7%, enriched to 3.7% with respect to oxygen concentration in air of 21%).

(26) FIG. 11 shows results of combustion temperature in the combustion experiment. As seen from this figure, when the position of the first tube in the parallel type lance or the pulverized coal blowing tube is changed to 0?, 60? and 180? around the axial line of the lance, the combustion temperature becomes highest at 60? or at a position that the blowing tubes for pulverized coal and LNG are above the oxygen blowing tube. This is considered due to the fact that the combustion field of LNG is made adjacent to the pulverized coal to heat the pulverized coal and oxygen is positioned beneath LNG and pulverized coal to efficiently mix with both LNG and pulverized coal and hence the combustion is promoted.

(27) In the blast furnace operation method adapted to the embodiment of the invention, when the pulverized coal (solid reducing material) 6, LNG (flammable gaseous reducing material) 9 and oxygen (combustible gas) are simultaneously blown through the lance 4 into the tuyere 3, the blowing area of the blowing tube (gap) can be largely maintained without making the outer diameter of the lance extremely large by using the parallel type lance prepared by bundling the respective blowing tubes in parallel and integrally housing them into the outer tube for lance. According to the invention method and lance, therefore, it can be attained to establish the increase of the cooling ability and the improvement of the combustibility, and hence the specific consumption of the reducing material can be decreased.

(28) Although the above embodiment is described by using LNG as a flammable gaseous reducing material, it is possible to use a town gas. In addition to the town gas and LNG, propane gas, hydrogen as well as converter gas, blast furnace gas and coke-oven gas produced in the the iron foundry can be used as the other gaseous reducing material. Moreover, shale gas may be utilized in equivalence to LNG. The shale gas is a natural gas obtained from a shale stratum, which is called as a non-conventional natural gas resource because it is produced in a place different from the conventional gas field.

DESCRIPTION OF REFERENCE SYMBOLS

(29) 1: blast furnace, 2: blowpipe, 3: tuyere, 4: lance, 5: raceway, 6: pulverized coal (solid reducing material), 7: coke, 8: char, 9: LNG (flammable gaseous reducing material)