JP2962179B2 - Measuring method of blast furnace charge - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for measuring the state of accumulation of a blast furnace charge for measuring the accumulation state of a furnace interior charge of a blast furnace.

[0002]

2. Description of the Related Art In a blast furnace, iron ore such as sinter or the like, which is a raw material, and coke are charged alternately in layers, and heated and reacted in the furnace to produce hot metal. In order to carry out various reactions with high efficiency and stability, it is important to optimize the gas flow distribution in the radial direction in the blast furnace. The gas flow velocity distribution in the blast furnace is grasped by an in-furnace sensor such as a shaft sonde provided in the upper part of the blast furnace, and a gas flow index (WO / F) in a blast furnace radial direction, that is, an ore drop amount WO
(Kg / min) The amount of gas rise F (Nm ³ / mi)
For example, n) is adjusted to a predetermined value (target) as shown in FIG. In addition, the gas flow index (WO /
F) is implemented by adjusting the coke (Coke) notch and the iron ore (Ore) notch of the movable armor to control the falling position of the charge, and to control the charge distribution. The controllability is shown in FIG.

In the operation action in this case, the sensitivity of the gas flow index (WO / F) of the center of the furnace and the wall of the furnace by the movable armor is provided by a charge distribution simulation model, and the coke (Cok) of the movable armor is provided.
e) Notches and iron ore (Ore) notches are adjusted to adjust the drop position of the charge. This charge distribution simulation model is a model that simulates a raw material deposition state such as a raw material deposition angle at the furnace top, a particle segregation, a flow-in, and the like based on charging conditions such as a raw material charging amount, a particle size, and a drop position. Many of them were constructed based on the results of filling surveys at the time, and the layer thickness of iron ore and coke, the amount charged, and the falling distance of the raw material did not always match the actual operation, and the number of measurements was also limited. It is not sufficient, and does not sufficiently reflect the distribution under actual operating conditions, such as the ore particle size distribution. The raw material deposition angle and deposition profile at the top of the blast furnace can be measured on a daily basis using a microwave profile meter.However, with regard to particle size segregation and coke layer inflow, there are only the charging investigation results at the time of the above-mentioned burning, and particle size segregation and coke For bed inflow, it is desired to improve the accuracy of the charge distribution simulation model.

As another method, a protective tube accommodating a magnetic material detection coil is placed in a blast furnace, and a layer thickness of a furnace interior material of the blast furnace is measured based on a change in inductance of the magnetic material detection coil. In the apparatus, a temperature compensation coil having a structure not affected by a magnetic substance in a furnace interior is accommodated in the protective tube, and thereby, a structure for compensating for the effect of temperature on a change in inductance of the magnetic substance detection coil is provided. And a method for measuring the behavior of a raw material stacked and charged in a blast furnace using an excitation type magnetic sensor, wherein the ore layer waveform output by the magnetic sensor is A method in which only the mixed layer waveform is reproduced from the composite waveform with the mixed layer waveform to obtain the mixed layer thickness and the mixing ratio thereof (Japanese Patent Laid-Open No. 63-11851). A jig body, a lifting / lowering drum provided in the housing body so as to be able to be driven forward and backward, and a sampling body provided with a sample collecting mechanism that can freely enter and exit from the entrance are mounted at the lower end, and the sampling body is loaded. An upper end is wound on an elevating drum, and an elevating rope is connected so as to be able to be rewound so that the surface is grounded and a sample is taken.A take-out port for taking out a sample taken on the side of the housing body is provided. A provided sampling device (Japanese Utility Model Laid-Open No. 64-51653) has been proposed.

[0005]

SUMMARY OF THE INVENTION The above-mentioned JP-A-59-28 is disclosed.
No. 507, the technology disclosed in JP-A-63-11851 can quantitatively evaluate the thickness of the iron ore layer and the mixed layer, but cannot measure the particle size distribution of iron ore or coke. is there. Further, the sampling device disclosed in Japanese Utility Model Application Laid-Open No. 64-51653 can sample the furnace interior material deposited in a state close to the actual operation, but the sampling amount and sampling depth at one time are not constant. And it is difficult to perform quantitative evaluation in combination with other sampling points in the radial direction.

SUMMARY OF THE INVENTION It is an object of the present invention to overcome the above-mentioned disadvantages of the prior art and to directly sample the furnace top charge during a blast furnace break while measuring the layer thickness and grain size of the charge. An object of the present invention is to provide a method for measuring a deposition state.

[0007]

Means for Solving the Problems The present inventors have intensively studied and studied to achieve the above object. As a result, the heat-resistant sampling bag and the supporting frame that supports it are arranged on the surface of the blast furnace charge that is shut off from the replacement manhole for the movable armor by wire ropes attached to both ends of the supporting frame in the longitudinal direction, After charging the raw material, the sampling device can be pulled up through a wire rope to collect the raw material deposited on the sampling bag, and by measuring the layer thickness and particle size distribution of the charged material in the radial direction inside the blast furnace, The present inventors have determined that the accumulation state of the charge can be accurately grasped, and reached the present invention.

[0008] That is, the present invention relates to a method for measuring the accumulation status of a blast furnace charge for measuring the accumulation status of a furnace interior charge of a blast furnace, comprising a sampling device combining a heat-resistant sampling bag and a support frame. It is charged from the manhole for replacement of movable armor through wire ropes attached to both ends in the longitudinal direction, placed on the surface of the raw material in the radial direction in the blast furnace with no wind, and then the raw material is charged, and then the sampling device is connected via the wire rope. This is a method of measuring the state of accumulation of the blast furnace charge, characterized by collecting the raw material deposited on the sampling bag and measuring the layer thickness and particle size of the charge in the radial direction in the blast furnace.

[0009]

According to the present invention, a sampling device combining a heat-resistant sampling bag and a support frame is inserted from a movable armor replacement manhole via wire ropes attached to both ends in the longitudinal direction of the support frame, and the air-conditioner is operated during a cold season. Placed on the surface of the raw material in the blast furnace radial direction, after that, after charging the raw material, pull up the sampling device via a wire rope,
By collecting the raw material deposited on the sampling bag and measuring the layer thickness and particle size distribution of the charged material in the blast furnace radial direction, the layer thickness and particle size distribution of the charged material in the blast furnace radial direction can be accurately grasped. Thus, the accuracy of the charge distribution simulation model can be further improved.

The sampling bag used in the present invention is made of a heat-resistant (> 1200 ° C.) cloth, a steel bag knitted into a sampling bag, a carbon fiber sampling bag, and a braided ceramic fiber. A sampling bag or the like can be used. In addition, the sampling bag is assumed to be shrinkable in the height direction.When placed on the surface of the raw material, the sampling bag is shrunk with the sampling port facing up, and after loading the raw material, the sampling device is pulled up via a wire rope. The configuration in which the raw material deposited on the sampling bag by extending the sampling bag in the height direction can be collected in the sampling bag is advantageous from the viewpoint of ensuring the raw material charging state.

[0011]

【Example】

Embodiment 1 The details of the method of the present invention will be described below with reference to FIGS. FIG. 1 is a perspective view of a raw material sampling apparatus of the method of the present invention, and FIG. 2 is a longitudinal sectional view for explaining a furnace top raw material sampling procedure. 1 and 2, reference numeral 1 denotes a support frame having the same length as the radius of the shaft portion of the blast furnace 2, and 3 denotes heat resistance (> 1200) supported by the support frame 1.
C), and can be shrunk in the height direction by a large number of sampling bags composed of cloths. 4, 5, 6, and 7 are wire ropes attached to both ends in the longitudinal direction of the support frame 1, and 8, 9 are blast furnaces 2.
By manipulating the wire ropes 4, 5, 6 and 7 from the manholes 8 and 9 at the manhole for replacing the movable armor provided at the upper part of the shaft part, a sampling device comprising the support frame 1 and a large number of sampling bags 3 is provided. It is configured so that it can be inserted into the blast furnace 2. 10 is a large bell, 11 is the surface of the charged raw material in the furnace, and 12 is the raw material charged on the charged raw material surface 11.

With the above configuration, when sampling the charged material in the blast furnace 2, when the blast furnace 2 is closed, the manholes 8, 9 for replacing the movable armor are opened, and then the wire ropes 4, 5,. 6 and 7, a sampling device including the support frame 1 and a number of sampling bags 3 is inserted into the blast furnace 2 from one of the manholes 8 and 9 for replacing the movable armor, and sampling is performed in the radial direction of the blast furnace 2. The bag 3 is positioned and placed on the charge surface 11. In this state, when the predetermined raw material is charged into the furnace with the large bell 10 opened, the charged raw material is contracted on the charged raw material surface 11 and the support frame 1 and the large number of sampling bags 3 are placed. Deposit on top. Thereafter, when the wire ropes 4, 5, 6, 7 are operated to pull up the sampling device composed of the support frame 1 and a large number of sampling bags 3, the charged material 12 deposited on the shrinked sampling bags 3 of the sampling device. Can be taken out by elongating the sampling bag 3, can be taken out of the furnace from one of the manholes 8 and 9 for replacing the movable armor, and a sample for one layer of the charged material in the radial direction of the blast furnace 2 can be taken. .

Therefore, by measuring the layer thickness and particle size of one sample of the raw material charged in each sampling bag 3 in the radial direction of the blast furnace 2, the layer thickness and particle size distribution of the raw material in the radial direction of the blast furnace 2 are measured. The accuracy of the segregation distribution simulation model can be used to improve the accuracy of the prediction of particle size segregation to approximate the measured value, and the radial gas flow index when operating the movable armor ( WO / F) response accuracy can be improved, the gas flow distribution in the blast furnace 2 can be optimized, and stable operation of the blast furnace 2 can be achieved.

Embodiment 2 Using the sampling apparatus of the embodiment 1, the furnace internal volume 27
In a blast furnace of 00 m ³ , a sample of one charged ore in the radial direction was taken at the time of the outage, and the particle size distribution in the radial direction was measured. The result is shown in FIG. FIG. 3 shows the calculation results obtained by simulating the particle size distribution of the raw material ore in the radial direction for each of the case where the parameters are corrected by reflecting the particle size distribution in the radial direction on the charge distribution simulation model and before the parameters are corrected. Shown in As shown in FIG. 3, by modifying the parameters of the charge distribution simulation model, it is possible to enhance the particle size segregation effect and approach the measured value. Thereby, as shown in FIG. 4, the simulation result after the parameter correction indicated by the solid line has a larger particle size segregation than the simulation result before the parameter correction indicated by the dashed line, and is in good agreement with the measured value. Therefore, the response accuracy of the radial gas flow index (WO / F) at the time of operating the Coke notch and the Ore notch of the movable armor could be improved.

[0015]

As described above, according to the method of the present invention, it is possible to accurately measure the deposition state of the charged material in the blast furnace, to control the distribution of the charged material in the blast furnace, and to control the charged material. The control of the type, the charging amount, and the like can be accurately performed, and the gas flow distribution in the furnace can be appropriately maintained, and the stable operation can be performed.

[Brief description of the drawings]

FIG. 1 is a perspective view of a raw material sampling apparatus according to the method of the present invention.

FIG. 2 is a longitudinal sectional view for explaining a furnace top raw material sampling procedure.

FIG. 3 is a graph showing a furnace top raw material particle size distribution (ore), and is a graph showing a relationship between an actually measured value at the time of wind-off, a dimensionless radius before and after parameter correction, and an ore weighted average particle size.

FIG. 4 shows an improved example of a charge distribution simulation model.
oke notch-Ore notch and furnace wall gas flow index (WO
/ F).

FIG. 5 shows a target of a radial gas flow index (WO / F). FIG. 5 (a) shows a relationship between a gas flow index (WO / F) of a furnace wall portion and the number of slips of> 0.3 m. Graph, (b)
The figure is a graph showing the relationship between the gas flow index (WO / F) at the center of the furnace and the number of slips of> 0.3 m.

FIG. 6 is a graph showing sensitivity of a gas flow index (WO / F) at a furnace center and a furnace wall by a movable armor, and is a graph showing a relationship between a Coke notch-Ore notch and a gas flow index (WO / F). is there.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Support frame 2 Blast furnace 3 Sampling bag 4, 5, 6, 7 Wire rope 8, 9 Manhole 10 Large bell 11 Surface of charged raw material 12 Raw material

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int. Cl. ⁶ , DB name) C21B 5/00 311 C21B 7/24 G01N 33/20

Claims (1)

(57) [Claims] 1. A method for measuring a deposition state of a blast furnace charge for measuring a deposition state of a furnace interior charge of a blast furnace, comprising: a sampling device in which a heat-resistant sampling bag and a support frame are combined; From the manhole for removable armor replacement via a wire rope attached to
It is placed on the surface of the raw material in the radial direction of the blast furnace while the wind is shut off, and after the raw material is charged, the sampling device is pulled up via a wire rope, and the raw material deposited on the sampling bag is collected. A method for measuring a deposition state of a blast furnace charge, comprising measuring a layer thickness and a particle size of the charge.