JPS5918436B2 - Pulverized coal pressurization and vibration filling equipment in coke ovens - Google Patents

Description

Detailed Description of the Invention The present invention applies pressing force and vibration force to the top surface of pulverized coal, which has been leveled after being charged into a coke oven carbonization chamber, by a vibrating member vibrated by a vibrator outside the furnace. The present invention relates to a vibratory filling device for charged pulverized coal in a coke oven carbonization chamber, which increases the bulk density of the charged pulverized coal.

An overview of large-scale industrial coke oven equipment is shown in Figures 1 and 2.
As shown in the figure, the coke oven carbonization chamber A has, for example, a width of 0.4 to 0.5 m, a height of 5 to 677 L, and a length of 14 to 15 m from the back side to the front side. The front and back sides are provided with opening/closing doors 1 and 2, respectively, and four to five pulverized coal inlets 3 are provided at the top.

Such a coke oven carbonization chamber A has a combustion chamber B disposed therebetween.
0 to 100 chambers are arranged side by side to constitute a furnace group, and the upper part of the furnace group is connected to a pulverized coal charging vehicle C having a number of pulverized coal hoppers 4 corresponding to the pulverized coal charging inlets 3 of the carbonization chamber A. The pulverized coal is charged into each carbonization chamber A by traveling in the direction shown in FIG.

Powdered coal is charged into the carbonization chamber A up to about 80% of its height, and unevenness 5 with a top is formed directly below each charging port 3 according to the angle of repose of the powdered coal (36° to 40°). .

On the back side of the coke oven group, a traveling cart F is installed which carries a leveler D for leveling the uneven surface 5 of the charged pulverized coal and an extruder E for pushing out the produced coke from the carbonization chamber A. ing.

That is, the leveler D is located at the upper level of the extruder E, and after charging the pulverized coal, it moves forward and backward several times from the back side to the front side of the carbonization chamber A, thereby evening out the uneven surface 5 of the charged pulverized coal. This is to secure the generated gas path 6, and to explain one example thereof, as shown in FIG. A beam main body 1 consisting of partition plates 10, 10, . It is equipped with a beam driving means 1-2 for moving the beam main body l forward and backward through a small door lower provided at the upper part of the back line 2 of the carbonization chamber A.

The beam driving means U consists of a driving drum 13 installed on a traveling cart F, front and rear fixed guide sheeps 14, 14, and an endless rope 15 wound around these. It is tied at the rear.

Therefore, by rotating the driving drum 13 in the forward and reverse directions, the beam main body (2) can enter and exit over the entire length of the carbonization chamber A, and the partition plate 10 scrapes the uneven surface 5 of the powdered coal to perform leveling.

After producing coke, the extruder E installed at the lower level of the leveler D opens the back doors 1 and 2 of the carbonization chamber A, pushes its extrusion ram 17 into the carbonization chamber A, and transfers the generated coke to the front door 1. The coke is pushed out and discharged through the coke guide car G on the side to the extinguishing car H.

The above is an overview of coke oven equipment, and the strength of dry distilled coke produced in such a coke oven is improved by increasing the charging bulk density of charged pulverized coal.

This is known both theoretically and empirically because the larger the bulk density, the smaller the distance between powdered coal particles.

That is, powdered coal particle size 3 dragon under 85%, moisture content 8%
Using powdered coal as an experimental material, we looked at the relationship between the deposition depth (d) and bulk density (tOrL/m) by changing the falling height from the charging port, as shown in Figure 4a, the larger the falling height, the more The larger the deposition depth, the larger the bulk density, and the relationship between the coal produced in the test furnace and the charging bulk density (tOrL/m) and the cold strength index and the bulk of the charged powder coal as shown in Figure 4C. It can be seen that the higher the density, the stronger the produced coke.

Conventionally, pulverized coal has been charged into the coke oven carbonization chamber by falling naturally from the top of the furnace, as described above.At the bottom of the coke oven, the falling height is large and the compaction effect due to the accumulated weight is large. Although the bulk density increases, the higher you go to the top, the lower the bulk density becomes.

With such a bulk density distribution in the furnace, the strength and quality of the produced coke are uneven, and no improvement in productivity can be expected.Especially when weakly coking coal is used, the coke has a low ring strength, making it difficult to manufacture pig iron. When it is charged into a blast furnace as a reducing agent, it becomes difficult to maintain air permeability and liquid permeability due to an increase in the pulverization rate, which may cause problems in blast furnace operation such as a decrease in productivity.

In order to advantageously solve the above-mentioned problems, the present invention provides a furnace on the leveled upper surface of the charged pulverized coal so that the bulk density of the pulverized coal charged in the carbonization chamber is almost uniform from the lower layer to the upper layer. The present invention provides a pressure vibration filling device that applies vibration while applying a predetermined load using a vibrating member vibrated by an external vibrator.

That is, according to the device of the present invention, as a physical force,
By applying gravity and vibration to the leveled upper surface of the charged pulverized coal, the bulk density of the pulverized coal can be increased uniformly in the upper, lower, and width directions of the coking chamber, thereby improving productivity and producing coke with high packing strength. The gist of its configuration is: a beam body that is provided so as to be able to enter and leave the coke oven over the entire length of the coke oven in contact with the top surface of the pulverized coal that has been leveled after being charged into the coke oven carbonization chamber; a vibrating member which is pivotably mounted to at least the tip of the beam body so as to be refractable with respect to the beam body and has a pressurizing, vibrating surface and a raising arm; and the vibrating member which is attached to the rear end portion of the beam body. a vibration exciter rigidly connected to the raising arm of the beam via a rond, and a lifting drive means attached to the rear end portion of the beam body for raising the vibrating member via the rond. It is characterized by this.

Embodiments in which the leveler beam itself is used as the beam body of the vibratory filling apparatus of the present invention will be described in detail with reference to the drawings.

In FIG. 5, 1 indicates two long side plates 9, 9 and partition plates 10, 10 attached at a required pitch in the longitudinal direction.
. . . A beam body is formed of a large number of bottom-cut sections, and an excitation member 18 is pivoted at the lower part of the rear end by a pivot shaft 19 at the tip of the beam body L so as to be able to bend and rise freely. ing.

The vibrating member 18 has a bottom plate 20 and a lifting arm 22, which serve as a pressurizing and vibrating surface for the powdered coal, and a weight 21 is attached to the upper surface of the bottom plate 20 to increase the pressurizing force as required.

A vibrating machine 23 and a cylinder 24 for raising and driving the vibrating member 18 are attached to the rear end portion of the beam body 1, which is always located outside the furnace. The tip of a rod 25 rigidly connected to the vibrator 23 is connected to the lifting arm 22 by a pin 26 .

This rod 25 serves as a means for transmitting vibrations to the vibrating member 18 by the vibrator 23, while the cylinder
Since the cylinder 24 is operatively connected to the vibrator 23, by actuating the cylinder 24, the vibrating member 18 can be raised via the rod 25 so as to be in line with the beam body l.

The excitation member 18 shown in FIG. 5 is made into a housing that can be stored in the tip section of the beam body 1, or the tip section of the beam body 1 may be used as the excitation member as is, as shown in FIG. .

The cylinder 24 is actuated by hydraulic pressure or the like supplied through a solenoid valve 27 and a supply hose 29 that can be wound or unwound together with a winding cable 28, and causes the vibration member 18 to move by stroking the rod 25. It can be raised so as to be in line with the beam body 1, or it can be bent and lowered.

When the vibrating member 18 is bent and lowered by the operation of the cylinder 24, the entire weight including the weight 21 is applied to the bottom plate 2 on the top surface of the leveled pulverized coal in the coke oven coal chemistry A.
0, and by vibrating the vibrator 23, the required vibration force can be applied.

To explain the operation of the pulverized coal vibratory filling device having the configuration described above, the pulverized coal charged into the coke oven coal chemistry A has an uneven surface 5 whose upper surface has a conical top directly below each charging port 3. , so we need to level this first.

During this leveling, the vibrating member 18 is raised so as to be in line with the beam body 1, and the beam driving means 11 consisting of the driving drum 13, endless rope 15, etc. shown in FIG. 3 is activated. The beam main body l is moved into and out of the carbonization chamber A over the entire length thereof.

The beam main body 1 collapses the convex portion on the upper surface of the pulverized coal, and also levels it with its partition plate 10, thereby leveling the upper surface of the pulverized coal.

After leveling two or three times, the vibrating member 18 is released, bent and lowered onto the top surface of the leveled pulverized coal to apply a pressing force due to the load, and the vibrating machine 23 outside the furnace is activated. The beam main body 1 is moved out of the carbonization chamber A while applying a vibration force to the upper surface of the powdered coal by the vibration member 18.

The filling pressure, frequency and acceleration of the vibrating member 18, whose vibrations are transmitted via the rod 25 by the vibrating machine 23 outside the furnace, as well as the moving speed of the beam body 1, are leveled after charging into the carbonization chamber A. It goes without saying that the bulk density of the upper layer of the pulverized coal is selected to be approximately equal to that of the bottom layer.

Note that the apparatus shown in FIGS. 5 and 6 is an example in which the leveler beam is also used as the beam body 8 and one vibrating member 18 is provided at its tip, but the beam body 1 is separate from the leveler beam. Alternatively, as shown in FIGS. 1a and 1b, two vibrating members 18, 18 or more vibrating members may be disposed directly on the beam body to shorten the vibrating filling work time. can be measured.

To explain an actual example of pulverized coal vibration filling work using the apparatus of the present invention, the coal was placed in a 32 m coke oven carbonization chamber, the filling surface pressure of the vibrating member was 1.58 x 10-2 Kg/c11t,
Frequency: 3600 VPM, vibration acceleration: 1.5 m/5e
C2, when the work was carried out at an excitation time of 30 SeC, the bulk density of the charged pulverized coal was increased by 0.1 ttIrL per 1.0 m' within a depth of 1 m from the upper layer of pulverized coal in the carbonization chamber, and coke powder was added to the core. The rate decreased by 2.88%.

As explained above, according to the pulverized coal vibratory filling device of the present invention, it is possible to produce coke that has a high ring strength and is almost uniform, which greatly improves the productivity of coke oven operation. In addition, it serves as a reducing agent with a low powderization rate during the operation of the blast furnace, and greatly contributes to improving the operation and productivity of the blast furnace.

[Brief explanation of the drawing]

Figures 1 and 2 are a side view and a plan view showing an overview of coke oven equipment, Figure 3 is a side view showing an example of a leveler, and Figures 4 a, b, and c are cold models of pulverized coal and produced coke. Figure 5 is a side view of the main part of the device according to the first embodiment of the present invention, FIG. 6 is a side view of the main part of the second embodiment of the same, and FIGS. FIG. 3 is a schematic side view of an embodiment using a vibrating member. A: Coke oven carbonization chamber, B: Combustion chamber, C: Powdered coal charging vehicle, D: Leveler, E: Extruder, F...... traveling truck,
G...Coke guide car, H...Fire engine, 1...Front door, 2...Back ruled line, 3...
... Powder coal charging inlet, 4 ... Powder coal hopper, 5.
...Uneven surface, 6... Gas path, 7...
...Small door opening, 1...Beam body, 9...
...Side plate, 10...Partition plate, 11...
・Guide roller, [λ...Beam driving means,
13... Drive drum, 14... Fixed guide sheave, 15... Endless rope, 16
...Clip, 17...Extrusion ram,
18... Vibrating member, 19... Pivoting shaft,
20... Bottom plate, 21... Weight, 22.
...Lifting arm, 23... Vibrator, 24.
.....Lifting drive cylinder, 25 ..... traction rod, 26 ..... pin, 27 ..... solenoid valve, 28 ..... winding cable , 29...
··hose.

Claims (1)

[Scope of Claims] 1. A beam body provided in contact with the upper surface of pulverized coal that has been leveled after being charged into a coke oven carbonization chamber so as to be able to enter and exit over the entire length of the carbonization chamber, and at least a distal end portion of the beam body with respect to the beam body. an excitation member that is pivotably mounted to be bendable and has a pressurizing surface, an excitation surface, and a lifting arm, and a rigid body attached to the rear end portion of the beam body and rigidly connected to the lifting arm of the excitation member via a rond; pulverized coal processing in a coke oven, characterized in that it is equipped with a vibration exciter, and a lifting drive means attached to the rear end portion of the beam body for raising the vibration member via the iron. Pressure-vibration filling island 2 A method for pressurizing pulverized coal in a coke oven according to claim 1, characterized in that a leveler beam is used as the beam main body, and a tip portion of the leveler beam is used as a vibrating member. Shaking filling device. 3. Pulverized coal in a coke oven according to claim 1, wherein a leveler beam is used as the beam main body, and the vibrating member is provided so as to be housed within a frame-shaped section of the leveler beam. Pressure and vibration filling equipment.