KR20130050551A - Apparatus for preventing abrasion of iron orc transportation equipment - Google Patents

Abstract

PURPOSE: An apparatus for preventing the abrasion of an iron ore transportation facility is provided to minimize the abrasion of a liner due to the impact and contact to loaded iron ores and to minimize the number of the replaced liners. CONSTITUTION: An apparatus for preventing the abrasion of an iron ore transportation facility comprises a liner(30) and one or more magnetic force generation units(40). The liner is mounted on the inner wall of the iron ore transportation facility and contacts to iron ores. The magnetic force generation units are coupled to the liner in order to apply magnetic force to the iron ores. Each magnetic force generation unit comprises a magnetic member and a protective member for protecting the magnetic member from the iron ores.

Description

Apparatus for preventing abrasion of iron orc transportation equipment

The present invention relates to a wear protection device of the iron ore transport equipment to minimize the wear caused by friction with iron ore in the equipment for transporting iron ore used as a raw material of the blast furnace.

The steel industry is a key infrastructure that supplies basic materials to the entire industry, including automobiles, shipbuilding, home appliances, and construction. Generally used in the steelmaking process, iron ore and coke are charged into a blast furnace (blast furnace), and hot air (oxygen) such as hot air or oxygen is injected through a tuyere, and the iron ore is injected. There is a blast furnace process (blast furnace process) which manufactures molten iron (pig iron) by reducing.

Hot air and oxygen blown into the air vents produce reducing gas by burning coke and pulverized coal in the blast furnace, and the generated high-temperature reducing gas rises and reduces iron ore as it rises inside the blast furnace, and the iron ore is melted by the high temperature. . The molten iron (slag, pig iron) and slag generated are discharged to the outside through the outlet of the blast furnace at a predetermined time, and then transported to the steelmaking process by the molten iron carrier (TLC).

That is, the operation of charging the fuel and raw materials into the blast furnace is to temporarily store the coke and iron ore produced in the sintering and coke plant as a pre-process in a blast furnace side storage hopper (not shown) using a transport facility (not shown), ㆍ The raw materials are weighed in the basis weight according to the blast furnace operation data and transferred to the upper part of the blast furnace through the fuel and raw material charging belt (not shown), stored in the hopper, and then loaded into the blast furnace. When it descends to this constant reference line, the soft and raw materials stored in each of the top hoppers are charged into the gourd by the charging chute in order by the detection signal of the charge level (LEVEL) measuring device installed on the blast furnace.

Here, the installation of wear-resistant members on the inner surface of the transport equipment, such as chute and hopper for supplying iron ore and / or sintered ore to a predetermined place in order to prevent wear and damage due to friction by the ore.

1 is a schematic cross-sectional view of a portion of a chute equipped with a protection liner as a wear resistant member.

As shown, the protection liner 3 is installed on the inner side of the chute 2 where the friction with the charge S is frequent. Therefore, the charge containing iron ore charged from the belt conveyor 1 to the chute 2 comes into collisional contact with the protection liner 3 provided on the chute 2. In this way, the wear of the chute 2 can be prevented by the protection liner 3 bonded to the inner surface of the chute 2.

However, when iron ore is continuously loaded into the chute 2, the collision continuously occurs with the protection liner 3, and eventually wear occurs on the surface of the protection liner 3 so that the protection liner 3 needs to be replaced.

At this time, the shorter the replacement cycle of the protection liner 3 has the problem that the overall equipment operation must be frequently stopped. That is, when the protection liner 3 is frequently replaced, there is a problem that the cost of the product increases and the efficiency of the blast furnace operation decreases as the service life of the protection liner 3 is short.

The present invention is to solve this problem, an object of the present invention is to provide a wear protection device of iron ore transport equipment that can increase the life of the liner by minimizing the wear of the liner by the impact contact with the charged iron ore.

Another object of the present invention is to provide an anti-wear device of an iron ore transport facility that facilitates maintenance when wear or breakage occurs in a liner due to continuous friction with iron ore.

In order to solve the above problems, the present invention is mounted on the inner wall of the transport facility for transporting iron ore is in contact with the iron ore; At least one magnetic force generating unit coupled to the liner to impart a magnetic force to the iron ore; provides an anti-wear device of the iron ore transport equipment comprising a.

The magnetic force generating unit includes a magnetic member generating magnetic force to attract iron ore, and a protective member coupled to an outer side of the magnetic member to protect the magnetic member from iron ore.

The magnetic force member may include a magnetic body generating a magnetic force and a support for supporting the magnetic body to be seated in a protective member, and the magnetic body may be formed of an electromagnet.

The protective member may be divided into a first protective cap on which the magnetic member is seated, and a second protective cap detachably coupled to the first protective cap.

An inclined surface is formed on the front upper surface of the first hobo cap, and a seating surface on which iron ore is seated is formed at the end of the inclined surface.

A cable hole is formed in the protection member such that a cable connected to the magnetic member is inserted.

According to the present invention, it is possible to increase the life of the liner by minimizing the wear of the liner due to the impact contact with the charged iron ore, thereby minimizing the number of replacement of the liner can improve the efficiency of the blast furnace operation.

1 is a cross-sectional view schematically showing a state in which iron ore is charged to the iron ore transport facilities according to the prior art.
Figure 2 is a schematic cross-sectional view of the iron ore transport equipment according to the present invention.
3 is a perspective view showing in detail the main portion of FIG.
Figure 4 is a perspective view of the magnetic material applied to the present invention.
5 is a cross-sectional view of a magnetic material applied to the present invention.
6 is an exploded cross-sectional view of a magnetic body applied to the present invention.
Figure 7 is a schematic cross-sectional view showing a state in which iron ore is charged to the iron ore transport equipment according to the present invention.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the wear protection device for iron ore transport equipment according to the present invention.

As shown in Figures 2 and 3, the wear protection device according to the present invention includes a liner (30).

The liner 30 is installed on the inner side of the chute 20 into which the charges including iron ore (hereinafter, collectively referred to as 'loads') are introduced to prevent friction between the inner wall of the chute 20 and the charges. . The liner 30 may be made of chrome cast iron plate or ceramic plate to have sufficient wear resistance.

The liner 30 may be installed on the entire inner surface of the chute, but when it is installed as a whole, the cost increases, so it is preferable to install the liner 30 intensively on the part where friction occurs frequently.

On the other hand, the liner 30 also serves to support the magnetic force generating unit to be described later. That is, a plurality of insertion holes 31 are formed in the liner 30 at predetermined intervals. In addition, the insertion hole 21 is formed in the wall surface of the chute 20 so as to correspond to the insertion hole 31. Therefore, the magnetic force generating unit can maintain the state after being inserted into the insertion hole 21 and 31 of the chute 20 and the liner 30.

In the present invention, the chute of the transport facility has been described as an example, but the transport facility applied to the present invention can be applied to all facilities in which iron ore (or sintered ore) is charged during blast furnace operation, such as a hopper.

In addition, the wear protection device of the present invention further includes a magnetic force generating unit (40).

The magnetic force generating unit 40 is installed at least one through the chute 20 and the insertion hole 21, 31 of the liner 30, the charge is generated by generating a magnetic force when the charge is in contact with the liner 30 Attract water to the water. Accordingly, the initial charges charged to the chute 20 are attracted to the magnetic force generating unit 40 by the attraction force of the magnetic force generating unit 40, and the subsequent charged matters rub against the liner 30. It can be charged without causing it.

As shown in FIGS. 4 to 6, the magnetic force generating unit 40 applied to the present invention includes a magnetic force member 100 for generating a magnetic force and a protective member 200 for protecting the magnetic force member 100. do.

The magnetic force member 100 includes a magnetic body 110 and a support 120 supporting the magnetic body 110.

The magnetic body 110 may be applied to an electromagnet. An electromagnet means a magnet that magnetizes when an electric current flows and returns to its original state which is not magnetized when an electric current is interrupted. For example, an electromagnet is a solenoid made by winding a coil around a cylindrical iron core, and a magnetic field is formed by flowing an electric current through a coil wound in a cylindrical shape, and a stronger magnetic field can be obtained by placing the iron core therein.

The support 120 is seated on the seating portion of the first protective cap to be described later in the state of supporting the magnetic body (110). In the center of the support 120, a cable hole 121 is formed in the horizontal direction in the drawing, and the cable hole 210 is inserted into the cable C for transmitting a signal to the magnetic material.

The protective member 200 is generally formed in a cylindrical shape, and divided into a first protective cap 210 and a second protective cap 220 for replacement or maintenance of the components constituting the magnetic body 110. It is preferable to comprise so that mutual attachment and detachment are possible.

For example, a female thread 213 may be formed on the rear inner circumferential surface of the first protective cap 210, and a male thread 222 may be formed on the outer circumferential surface of the front end of the second protective cap 220. Of course, the male thread is formed on the outer peripheral surface of the rear end of the first protective cap 210, the female thread may be formed on the inner peripheral surface of the front end of the second protective cap 220, the magnetic member accommodated inside the first protective cap 210 The fastening part 221 protrudes a predetermined length at the tip of the second protective cap 220 so that the 100 can be more stably fixed, and a male thread 222 is formed on the outer circumferential surface of the fastening part 221. It is preferable that the screw thread 213 is screwed with the first protective cap 210 formed.

The interior of the first protective cap 210 is provided with a space 211 that can accommodate the magnetic force member 100. In addition, a seating portion 212 may be provided in the space 211 so that the support 120 of the magnetic member 100 may be seated. The seating part 212 may be formed in an arc shape on a lower surface of the space portion 211, and a bottom surface of the support body 120 seated therein may also be formed in an arc shape so that the support body 120 is inside the first protective cap 210. Can be safely seated on

An inclined surface 214 is formed on an upper end surface of the first protective cap 210. The inclined surface 214 allows the charges attracted by the magnetic force to be seated and more easily maintained in the magnetic force generating unit 40, while the charges can be easily dropped from the first protective cap when the magnetic force is released. Make sure Accordingly, the above-described magnetic body 110 is also preferably formed to be inclined at an angle corresponding to the inclined surface 214. Furthermore, a mounting surface 215 in a horizontal state may be formed at the end of the inclined surface 214 so that the contents can be more smoothly maintained.

In the inner center of the second protective cap 220, the cable hole 223 is formed in a horizontal direction so as to correspond to the cable hole 121 formed in the support member 120 of the magnetic member 100 described above.

Referring to the operation of the wear protection device of the iron ore transport equipment according to the present invention configured as described above are as follows.

When the belt conveyor 10 is started by a signal of a controller (not shown), the charge S including iron ore on the belt conveyor 10 is loaded into the chute 20 for transporting it.

At this time, the control unit sends a signal to the magnetic force generating unit 40 to impart a magnetic force to the iron ore charged in the chute 20. That is, the magnetic force generating unit 40 received a signal through the cable (C) connected to the control unit is to generate a magnetic force to attract the iron ore.

As such, when the magnetic force generating unit 40 applies an attraction force to the iron ore and maintains the state, the iron ore initially loaded into the chute 20 maintains the state attached to the magnetic force generating unit 40 and the liner 30. do.

Thus, the charges S subsequently loaded into the chute 20 from the belt conveyor 10 are not in direct contact with the liner 30, but rather with the charges already attached to the liner 30, the chute It will fall to the lower side of 20.

Accordingly, the friction between the liner 30 and the charges installed on the inner wall surface of the chute 20 can be minimized, thereby reducing wear of the liner and consequently increasing its life.

20; Chute 21; Insertion hole
30; Liner 31; Insertion hole
40; Magnetic force generating unit 100; Magnetic force
110; Magnetic body 120; Support
200; Protective member 210; 1st protective cap
211; Space 212; Seat portion
213; Female thread 214; incline
315; Seating surface 220; 2nd protective cap
221; Fastening section 222; Male thread
223; Cable hole

Claims (7)

A liner mounted on an inner wall of the transport facility for transporting iron ore and in contact with the iron ore;
At least one magnetic force generating unit coupled to the liner to impart a magnetic force to the iron ore.
The method of claim 1,
The magnetic force generating unit is a wear preventing device of the iron ore transport equipment, characterized in that it comprises a magnetic member for generating magnetic force to attract iron ore, coupled to the outside of the magnetic member to protect the magnetic member from the iron ore.
The method of claim 2,
The magnetic force member is a wear preventing device of the iron ore transport equipment, characterized in that it comprises a magnetic body for generating a magnetic force, and a support that is supported in the magnetic body seated in the protective member.
The method of claim 2,
The protective member is a wear protection device of the iron ore transport equipment, characterized in that the magnetic protection member is divided into a first protective cap and a second protective cap detachably coupled to the first protective cap.
5. The method of claim 4,
Wear prevention device of iron ore transport equipment, characterized in that the inclined surface is formed on the front upper surface of the first hobo cap.
The method of claim 5,
At the end of the inclined surface wear prevention device of the iron ore transport equipment, characterized in that the seating surface on which iron ore is formed.
The method of claim 2,
The wear protection device of the iron ore transport equipment, characterized in that the cable hole is formed in the protective member so that the cable is connected to the magnetic member is inserted.

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