KR20100107755A - Apparatus for abservation of materials distribution in furnace - Google Patents

Abstract

PURPOSE: A test apparatus for material distribution in a furnace is provided to test material distribution in various charging conditions without difficulties and threat of accidents. CONSTITUTION: A test apparatus for material distribution in a furnace comprises a distribution locker(10), a charging bunker(20), a blast-furnace charging unit(30), a furnace main body(40), a bottom plate(42), a bottom plate lifting unit(70) and a supporting frame(60). The charging bunker is installed under the distribution locker. The blast-furnace charging unit is installed under the charging bunker and equipped with a distribution chute(35). The furnace main body is installed under the blast-furnace charging unit. The bottom plate is installed inside the furnace main body and able to move up and down. The bottom plate lifting unit supports and lifts the bottom plate. The supporting frame supports the furnace main body.

Description

Apparatus for abservation of materials distribution in furnace}

The present invention relates to a blast furnace charge distribution test apparatus that can be tested the distribution state of the blast furnace charge.

The blast furnace is a countercurrent reactor in which the reduction gas generated by the coke combustion and the iron ore reduced by this are lowered and converted into molten iron. It became an element.

In order to properly control the gas distribution in the blast furnace, it is necessary to control the charging pattern and profile of the charges charged into the blast furnace through the distribution chute of the charging device.

For this purpose, it is most preferable to directly observe the charging state of the furnace, but since it is very difficult and dangerous to observe the operation of the furnace in the actual operating state, it is necessary to investigate the distribution of the blast furnace charge through the experiment.

Accordingly, an object of the present invention is to provide a blast furnace charge distribution test apparatus which is capable of charging the charges in a state close to reality and examining the distribution state thereof, which is devised by the necessity as described above.

The present invention for achieving the above object,

A distribution locker;

A charging bunker installed at a lower portion of the distribution locker;

A top loading device installed at a lower portion of the charging bunker and having a distribution chute;

A main body installed in the lower part of the top charging device;

A bottom plate installed to be movable up and down inside the furnace body;

A bottom plate elevating device for supporting the bottom plate and elevating it;

A support frame for supporting the furnace body;

.

The bottom plate elevating device may include a male screw shaft rotatably connected to an upper end of the bottom plate and screwed to a female thread guide installed on a support plate at the bottom of the main body, a servo motor mounted to the bottom plate, and the male screw shaft. And a sprocket provided on each output shaft of the servomotor, and a chain connecting the sprockets.

In addition, the distribution locker, the charging bunker, the top loading device, the support structure for supporting it is installed around the whole of the main body, the skip is provided with a movable frame for holding the relay in the side of the support structure, A hoist for lifting the movable frame is installed on the upper frame of the support structure so as to move left and right, and a belt conveyor is installed on the support structure to transfer the charged material dropped from the relay tank to the upper portion of the distribution locker. It is done.

In addition, a charge discharge door is provided on the lower side of the furnace body.

In addition, the furnace body is characterized in that made of a transparent material.

In addition, a camera may be installed in the furnace body.

In addition, a distribution measuring device having a sensor for detecting a charge distribution profile of the bottom plate and moving the sensor in a radial direction of the inner space of the furnace body may be installed in the furnace body.

According to the present invention as described above, it is possible to observe the charge distribution profile in the furnace without difficulty of work and safety threats, so that the charge distribution experiment can be carried out while varying the charging conditions of the charge.

Therefore, it is possible to obtain abundant load distribution data under various charging conditions, it is possible to establish the optimal blast furnace load distribution control technology based on this.

Hereinafter, with reference to the accompanying drawings, the present invention will be described in detail.

1 is a front view of the blast furnace load distribution experimental apparatus according to the present invention, Figure 2 is an enlarged view of the bottom plate lifting apparatus of one configuration of the present invention, Figure 3 is a plan view of the bottom plate lifting device.

The present invention includes a distribution locker 10, a charging bunker 20, a top loading device 30 and a main body 40, which simulates a distribution locker, a charging bunker, a top loading device and a no shaft of an actual blast furnace.

The distribution locker 10 is a device for dividing the supplied iron ore and coke into a distribution chute provided therein to distribute the supplied bunker 20, the charging bunker 20 is a symmetrical shape of the left and right charging bunkers The iron ore and coke are distributed and stored, and the lower door (valve) is opened and closed to supply iron ore and coke to the lower top charging device 30 according to the charging control logic by the computer. Apparatus for dropping the iron ore and coke supplied from the charging bunker 20 to the bottom of the furnace body 40 having a distribution chute (35; rotatable and tilt angle is adjusted) which is operated controlled by the charging control logic. to be.

The lower part of the main body 40 is provided with a sea plate 42 which is movable up and down inside the main body 40, the support plate 44 is coupled to the lower end of the main body 40 fixed to the outside do.

The support plate 44 is supported by a support frame 60 placed on the factory floor.

The support frame 60 is provided with wheels 65 to move along the rail.

On the other hand, the bottom plate 42 is provided with a bottom plate elevating device 70 is to maintain a fixed state at the time of charging, and if necessary, can be lowered to simulate the state of loading water by the discharge of molten iron in the blast furnace. It is supposed to be.

As shown in FIG. 2, the bottom plate elevating device 70 includes a male screw shaft 71 supporting the bottom plate 42, a servomotor 72 mounted on the bottom plate 42, and the male screw shaft 71. ) And sprockets 73 and 74 provided on the output shaft of the servomotor 72, and a chain 75 connecting these sprockets 73 and 74, respectively.

The upper end of the male screw shaft 71 is connected to the lower surface of the bottom plate 42 in a rotatable state, and the lower end is screwed to the cylindrical female screw guide 76 installed on the support plate 44.

Therefore, when the servomotor 72 is operated, power is transmitted through the chain 75 so that the male screw shaft 71 is rotated, and the male screw shaft 71 is screwed to the fixed position female screw 76. It can be raised and lowered with respect to the female thread guide 76 according to the rotation direction.

Therefore, the bottom plate 42 is raised before the start of the experiment, and the charge can be simulated by the discharge of the molten iron in the blast furnace by lowering by appropriately adjusting the rotational speed of the servomotor 72 while charging the charge. .

On the other hand, the furnace body 40 is made of transparent acrylic so that the inside can be visually observed from the outside.

In addition, the bottom plate 42 and the support plate 44 may also be composed of two semicircular plates in case the furnace body 40 is vertically divided so that the main body 40 can be opened after charging. Reference)

Also in this case, the bottom plate elevating device 70 having the same configuration as that described above is provided on each semicircle plate. That is, the servo motor 72 is provided in the center of the string of the semi-circle plate, the male screw shaft 71 is provided in both the left and right sides of the semicircle and the center of the arc, and the chains are surrounded by the entire sprockets 73 and 74 provided therein. Install (75).

The lower support frame 60 is also divided into two in the same manner, of course.

On the other hand, the support structure 80 around the blast furnace installation in order to install a device for supplying the contents to the distribution locker 10 to support the entire blast furnace facility (from the distribution locker to the main body). Install it.

The support structure 80 is configured by interconnecting (welding, bolting) H-beams, angles, pipes, wires, and the like, and may be variously designed and manufactured according to the size and shape of the support object, so a detailed description of the structure is omitted. do.

The support structure 80 may be separated by the floor as necessary, and installed by the operator to access the respective parts of the support object, it is possible to install a railing for the safety of the worker.

On the other hand, the charges such as iron ore and coke is carried in the relay tank (1).

One side of the support structure 80 is provided with a skip 90 having a movable frame for mounting the relay tank 1 (connected to the support structure 80 to maintain the installation strength), and also The upper frame of the support structure 80 is provided with a hoist 100 that a rail is installed to move along the rail.

Therefore, when the relay nail 1 is moved to the lower portion of the skip 90 by the balance, the relay nail 1 is seated on the movable frame of the skip 90, and the hoist 100 is in the state. By raising the movable frame, the relay tank 1 is moved upward.

Subsequently, the hoist 100 moves along the upper frame, so that the relay nail 1 is moved to the upper portion of the belt conveyor 110, and the charge is dropped onto the belt conveyor 110 by opening the lower door of the relay drum. . The belt conveyor 110 is also installed on the support structure (80).

Thereafter, the charge is moved along the belt conveyor 110 to be dropped into the distribution locker 10.

The charged material introduced into the distribution locker 10 is dropped through the distribution chute 35 of the top loading device 30 through the charging bunker 20 as described above, according to the operation of the distribution chute 35. 40 is laminated to the bottom plate 42.

In this way, while charging the charged material into the inside of the furnace body 40, the experimenter observes and records the drop trajectory of the charge and the distribution shape of the charge formed in the bottom plate 42 through the transparent furnace body 40. do.

In this case, when the camera is installed on the inner wall of the furnace body 40, the photographed image may be checked through an external computer monitor, and the image may be stored and used as data.

The camera can be installed wherever the dispensing chute 35 and the contents falling from it can be avoided. The camera can be easily installed using fastening parts such as mounting brackets and bolts with simple structure, and has a protective cover. It is desirable to.

In addition, the furnace body 40 may be provided with a distribution measuring device having a sensor for transmitting and receiving laser or ultrasonic waves.

The distribution measuring device detects that the transmitted laser or ultrasonic wave is reflected back to the surface of the charge formed in the bottom plate 42 to detect the distribution profile of the charge, and radially moves the upper part of the bottom plate 42 in the radial direction. It is preferable to be installed to move to.

Therefore, the distribution measuring device is a moving device for moving the sensor from the inner wall of the furnace body to the center of the furnace in the state where the charging of the charge is stopped, and then back to the original position, or in a path crossing the diameter of the furnace body. Include.

Since the mobile device will be easily designed by those skilled in the art using an appropriate mechanism, detailed description thereof will be omitted.

Data measured from the distribution measuring device may also be output as a numerical value or an image through a computer monitor, and may be stored in a storage medium.

Thereafter, the bottom plate elevating device 70 is operated to lower the bottom plate 42 at the same rate as the actual molten iron drop rate, and as a result, the distribution profile of the changed contents is observed, measured, and recorded.

In this way, it is possible to observe the charge distribution profile in the furnace without any difficulty and risk, so that the charge distribution experiment can be carried out while varying the particle size of the charge or the operation pattern of the distribution chute 35.

Therefore, it is possible to obtain the charge distribution data under various charging conditions, it is possible to establish the optimal blast furnace charge distribution control technology based on this.

In addition, the lower side of the furnace main body 40 is provided with a charge discharge door 46 provided with a handle 48 at equal intervals on the circumference. The upper end of the charge discharge door 46 is hinged to be rotatable to the door gate (door hole installed in the furnace body).

Therefore, in the state where the bottom plate 42 is completely lowered, the charge discharge door 46 may be opened to discharge the internal charges to the outside.

1 is a front view of the blast furnace load distribution experimental apparatus according to the present invention,

Figure 2 is an enlarged view of the bottom plate lifting device which is one configuration of the present invention,

3 is a plan view of the bottom plate lifting device.

* Description of the symbols for the main parts of the drawings *

10: distribution locker 20: charging bunker

30: tripper charging device 40: the main body

42: bottom plate 60: support frame

70: bottom plate lifting device 71: male screw shaft

72: servomotor 73,74: sprocket

75: chain 76: female thread guide

80: support structure 90: skip

100: hoist 110: belt conveyor

Claims (7)

A distribution locker; A charging bunker installed at a lower portion of the distribution locker; A top loading device installed at a lower portion of the charging bunker and having a distribution chute; A main body installed in the lower part of the top charging device; A bottom plate installed to be movable up and down inside the furnace body; A bottom plate elevating device for supporting the bottom plate and elevating it; A support frame for supporting the furnace body; Blast furnace load distribution experiment apparatus comprising a. The method according to claim 1, The bottom plate elevating device is rotatably connected to the bottom plate, the male screw shaft is screwed to the female thread guide installed on the support plate of the lower body, the servo motor mounted on the bottom plate, the male screw shaft and servo motor The blast furnace charge distribution experiment apparatus, characterized in that it comprises a sprocket provided on each output shaft of the chain, and the chain connecting the sprockets. The method according to claim 1, The distribution locker, the charging bunker, the top loading device, the support structure for supporting it is installed around the entire main body, the skip is provided with a movable frame to hold the relay in the side of the support structure, the support A hoist for lifting the movable frame is installed on the upper frame of the structure so as to move left and right, and a belt conveyor is installed on the support structure to transfer and drop the charged material from the relay tank to the upper portion of the distribution locker. Blast furnace charge distribution experiment device. The method according to claim 1, Blast furnace loading distribution apparatus, characterized in that the charge discharge door is provided on the lower side of the furnace body. The method according to claim 1, The furnace body is a blast furnace load distribution experiment device, characterized in that made of a transparent material. The method according to claim 1, Blast furnace loading distribution experiment device, characterized in that the camera is installed inside the furnace body. The method according to claim 1, Blast furnace charging characterized in that the inside of the furnace body, having a sensor for detecting the load distribution profile of the bottom plate and a distribution measuring device having a moving device for moving the sensor in the radial direction of the inner space of the furnace body. Water distribution experiment device.

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