KR102340968B1 - Electric arc furnace - Google Patents

Abstract

The present invention relates to an electric arc furnace, comprising: a furnace shell, an electrode, a furnace shell moving mechanism for supporting the furnace shell so as to be movable on an installation surface, and a first insulating member for electrically insulating between the furnace shell and the furnace shell moving mechanism do.

Description

Electric arc furnace

The present invention relates to an electric arc furnace, and more particularly, to an electric arc furnace in which a metal is melted while moving a furnace shell.

In an arc furnace, which is a kind of electric arc furnace for melting a metal material, so-called hot spots and cold spots are formed in the inner space of the furnace shell containing the metal material. The hot spot is located close to the electrode and the metal material is likely to melt at the hot spot. The cold spot is far from the electrode, and it is difficult for the metal material to melt at the cold spot. At the cold point, it takes a long time to melt the metal material, and thus there is a problem that the melting of the metal material proceeds uniformly as a whole. In order to solve this problem, Patent Document 1 proposes a process in which a furnace shell is arranged to rotate about an axis extending vertically with respect to an electrode, and a cold spot and a hot spot are exchanged. In such an electric arc furnace, thermal non-uniformity in the furnace can be eliminated, and wasteful consumption, without consuming power for pumps in an additional water cooling section of the shaft furnace, etc. and additionally supplying burner combustion energy, etc. for proper treatment configuration of exhaust gas The amount of electric power can be reduced by rotating the furnace shell.

Japanese Laid-Open Patent Publication No. 2014-40965

In the arc furnace, a large current flows through an electrode inserted into the furnace shell to melt the metal material. Due to the current flowing through the electrode, the current can also flow through the furnace shell. In particular, when the current flowing through the electrode is alternating current, the induced current continuously flows on the surface of the furnace shell. In order to perform the rotational arrangement of the furnace shell, a furnace shell moving mechanism having a movable part such as a bearing is employed. When a leakage current flowing through a metallic material in the furnace shell or an induced current flowing through the surface of the furnace shell flows in this kind of movable part, this current may damage the movable part and impair the function of the movable part. . For example, in a state where an electrode is inserted into a furnace shell and an electric current is supplied, a leakage current flowing through a metal material in the furnace shell or an induced current generated in the furnace shell flows to a member such as a bearing of the furnace shell moving mechanism and causes a spark , even if the furnace shell moving mechanism is in a fixed state, the constituent members of the furnace shell moving mechanism may be damaged, and thus the continuous smooth movement of the furnace shell may be disturbed.

Accordingly, it is an object of the present invention to provide an electric arc furnace having a moving furnace shell, which can prevent an electric current from flowing in a furnace shell moving mechanism for moving the furnace shell.

In order to solve the above problems, the electric arc furnace of the present invention:

raw shell;

electrode;

a furnace shell moving mechanism for supporting the furnace shell to be movable on the installation surface; and

and a first insulating member that electrically insulates between the furnace shell and the furnace shell moving mechanism.

wherein the furnace shell moving mechanism includes a first portion fixed to the installation surface and a second portion fixed to the furnace shell and movable relative to the first portion, the first portion being electrically connected to the second portion desirable.

In this case, the electric arc furnace further includes a connecting wire electrically connecting the first and second portions of the furnace shell moving mechanism, and the connecting wire has a length that can follow the entire movable range of the second portion. desirable.

Preferably, the furnace shell and the furnace shell moving mechanism are independently grounded.

In addition, electric arc furnaces:

a furnace roof covering the opening of the furnace shell;

a furnace roof moving mechanism for moving the furnace roof relative to the furnace shell; and

It is preferable to further include a second insulating member that electrically insulates between the furnace roof moving mechanism and the furnace shell. In this case, it is preferable that the furnace shell and the furnace roof moving mechanism are independently grounded.

In the electric arc furnace according to the present invention, an insulating member (first insulating member) is provided between the furnace shell and the furnace shell moving mechanism. Therefore, even when a current flows through the furnace shell by the current flowing through the electrode, the current flowing through the furnace shell is prevented from flowing from the furnace shell to the furnace shell moving mechanism. As a result, the furnace shell moving mechanism is prevented from being damaged by the electric current.

wherein the furnace shell moving mechanism includes a first portion fixed to the installation surface and a second portion fixed to the furnace shell and movable relative to the first portion, and when the first portion is electrically connected to the second portion, The first part and the second part become equipotential. Therefore, even when a current flows in the furnace shell moving mechanism due to dielectric breakdown of the first insulating member that electrically insulates between the furnace shell and the furnace shell moving mechanism, the phenomenon that the current flows over a wide area within the furnace shell moving mechanism is easily doesn't happen As a result, it is possible to prevent the furnace shell moving mechanism from being seriously damaged with high accuracy.

In this case, when a connecting wire electrically connecting between the first and second portions of the furnace shell moving mechanism is provided and the connecting wire has a length that can follow the entire movable range of the second portion, the second portion is Even if it is moved with respect to the first part, it is possible to prevent the connecting wire from being damaged or from applying excessive force.

Further, when the furnace shell and the furnace shell moving mechanism are independently grounded, it is possible to more reliably prevent the current flowing in the furnace shell from flowing into the furnace shell moving mechanism.

Furthermore, when the electric arc furnace further includes a furnace roof covering the opening of the furnace shell, a furnace roof moving mechanism for moving the furnace roof with respect to the furnace shell, and a second insulating member electrically insulating between the furnace roof moving mechanism and the furnace shell , it is also possible to prevent the current flowing in the furnace shell from flowing into the furnace roof moving mechanism. Accordingly, it can also be prevented that the members constituting the furnace roof moving mechanism are damaged by the electric current.

In this case, if the furnace shell and the furnace roof moving mechanism are independently grounded, it is possible to more reliably prevent the current flowing in the furnace shell from flowing to the furnace roof moving mechanism.

1 is a side view showing an electric arc furnace according to an embodiment of the present invention.
Fig. 2 is a perspective view showing a furnace shell moving mechanism and a furnace shell insulating member, the furnace shell insulating member being shown by a dotted line in a perspective manner.
3 is an enlarged cross-sectional view of the furnace shell moving mechanism;
4A and 4B are diagrams showing a specific embodiment of a method of attaching a bearing connection wire, wherein FIG. 4A shows a state viewed from the upper side of the furnace shell moving mechanism, and FIG. 4B is a cut along the line AA in FIG. 4A. It is a cross-sectional view, and the broken line in FIG. 4A shows the state of the bearing connecting wire when the furnace shell is rotated by 50°.

An electric arc furnace according to an embodiment of the present invention will be described with reference to the drawings.

(composition of electric arc furnace)

1 to 4B show an electric arc furnace 1 according to an embodiment of the present invention. The electric arc furnace 1 is installed on the platform 90 . The electric arc furnace 1 has an electric arc furnace (arc furnace) similar to that described in Patent Document 1 as a main body portion, and includes a furnace shell 10 , a furnace roof 20 , and an electrode 25 . Further, the electric arc furnace 1 includes a furnace roof holding unit 40 having a furnace shell moving mechanism 30 and a furnace roof moving mechanism 43 . In addition, the electric arc furnace 1 includes a furnace shell insulating member (first insulating member) 51 and a furnace roof insulating member (second insulating member) 52 as insulating members, a furnace shell grounding wire 61, and a furnace shell moving It also includes a mechanism grounding wire 62 and a furnace roof moving mechanism grounding wire 63 .

The furnace shell 10 is formed as a vessel having a substantially cylindrical bottom, having an opening thereon. The furnace shell 10 is formed of a material in which a steel shell is provided on the outside of a refractory material made of metal oxide.

The furnace roof 20 is formed in a substantially disk shape and can close the opening of the furnace shell 10 . The furnace roof 20 is held by the furnace roof holding unit 40 and performs rotational movement and up/down movement on the furnace shell 10 so that the opening of the furnace shell 10 is closed and the opening is opened. move between states Even if the furnace roof 20 is formed of a material similar to that of the furnace shell 10, the insulator is exposed at each portion of the furnace roof adjacent portion through which an electrode 25, which will be described later, penetrates the furnace roof. Accordingly, electrical insulation is maintained between the furnace roof and the electrode 25 .

In the present embodiment, three electrodes 25 (only two electrodes are shown in FIG. 1 ) penetrate the furnace roof 20 from the upper side toward the inner space of the furnace shell 10 . The three electrodes 25 are arranged to form a substantially equilateral triangle about the central axis of the furnace shell 10 . When a metal material such as an iron scrap material is contained in the furnace shell 10 and an electric current such as a three-phase alternating current is supplied to the three electrodes 25 to perform discharge, the metal material may be melted. The electrode 25 is electrically insulated from each of the furnace shell 10 and the furnace roof 20 .

The furnace shell 10 is supported by a platform (installation surface) 90 via a furnace shell moving mechanism 30 . As shown in Fig. 2, the furnace shell moving mechanism 30 includes a support frame 31 made of metal and having an upper surface and a bottom surface each having a substantially annular shape. The furnace shell 10 is placed on the upper surface 31a, which is the upper surface of the support frame 31, through the furnace shell insulating member 51 having a substantially ring-plate shape. A plurality of concave portions 31c are provided on the upper surface 31a of the support frame 31 . The furnace shell 10 is fixed on the support frame 31 by not only the weight of the furnace shell 10 itself, but also by coupling the convex portions (not shown) formed in the furnace shell 10 and the concave portions 31c. The furnace shell insulating member 51 electrically insulates between the furnace shell 10 and the support frame 31 . The gear member 31b is formed along the inner circumferential surface of the support frame 31 . An insulating resin is filled between the bottom portion of the furnace shell 10 and the support frame 31 in such a way as to hide the furnace shell insulating member 51 therebetween. Accordingly, each gap formed between the bottom of the furnace shell 10 , the furnace shell insulating member 51 and the support frame 31 is filled with an insulating material.

The support frame 31 is supported by a bearing 32 . 3 is a cross-sectional view showing a part of the furnace shell moving mechanism in the vicinity of the bearing 32 . Bearing 32 is attached to an attachment base 34 made of metal that is secured on platform 90 . The bearing 32 is composed of a known swing bearing, and an outer wheel (first part) 32a, an inner wheel (second part) 32b, and an outer wheel 32a and inner made of metal, respectively. rolling elements (not shown) arranged between the wheels 32b. The inner wheel 32b is swingable with respect to the outer wheel 32a. The outer wheel 32a is fixed to the attachment base 34 and the inner wheel 32b is fixed to the gear member 31b of the support frame 31 . The bearing connecting wire 33 electrically connects between the support frame 31 and the attachment base 34 . The bearing connecting wire 33 has a sufficient length to follow the entire swingable or rotatable range of the support frame 31 . Since the outer wheel 32a of the bearing 32 is made to contact the attachment base 34 and the inner wheel 32b is made to contact the support frame 31, the outer wheel 32a and the inner wheel 32b are electrically connected to each other by means of a bearing connecting wire (33).

A gear portion 35 having two gears (a first gear 35a and a second gear 35b) meshing with each other is provided on the inner peripheral side of the support frame 31 . Although only one gear part 35 is shown in FIG. 2 , another gear part similar to the gear part 35 is provided at a position opposite to the inner periphery. The first gear 35a constituting the gear part 35 meshes with the gear member 31b provided on the inner circumferential surface of the support frame 31 . The rotation shaft of the second gear 35b meshed with the first gear 35a is connected to an output shaft of a hydraulic motor (not shown).

The support frame 31 may be made to vibrate on the bearing 32 by driving the hydraulic motor of the gear part 35 . As a result, the furnace shell 10 is rotated (shaken) on the platform 90 . When the furnace shell 10 rotates, the angular position of the electrodes 25 along the plane of the platform 90 does not change. Accordingly, the relative arrangement between the furnace shell 10 and the electrode 25 changes according to the rotation of the furnace shell 10 . A stopper mechanism (not shown) for holding the support frame 31 in a state in which the rotation of the support frame 31 is stopped may be appropriately provided on the inner peripheral side of the support frame 31 .

The furnace roof holding unit 40 is provided on a common platform 90 on which the furnace shell 10 is installed via the furnace shell moving mechanism 30 . The furnace roof holding unit 40 supports the furnace roof 20 by the furnace roof support part 41 and performs rotational movement and up/down movement of the furnace roof 20 . The furnace roof holding unit 40 also has a function of performing and maintaining the up/down movement of the electrode 25 by the electrode supporting part 42 . Accordingly, the furnace roof holding unit 40 can adjust the upper/lower positions of the electrodes 25 according to the molten state of the metal material in the furnace shell 10 or the like. Up/down and rotational movement of the furnace roof 20 and up/down movement of the electrode 25 are driven by a furnace roof movement mechanism 43 provided with a bearing and a hydraulic motor. The furnace roof support 41 and the electrode support 42 are electrically insulated from each other. The furnace roof insulating member 52 is provided between the furnace roof support 41 and the furnace roof moving mechanism 43 . Accordingly, the furnace roof moving mechanism 43 is electrically insulated from the furnace roof 20 and the furnace roof support 41 . The furnace roof moving mechanism 43 side portion of the furnace roof holding unit divided by the furnace roof insulating member 52 is grounded with the furnace roof moving mechanism grounding wire 63 .

The platform 90 on which the electric arc furnace 1 is installed is a stand made of metal. The platform 90 is grounded by a furnace shell moving mechanism ground wire 62 . The attachment base 34 of the furnace shell moving mechanism 30 is fixed on the platform 90 in a contact manner. Accordingly, the bearing 32 of the furnace shell moving mechanism 30 is grounded with the furnace shell moving mechanism grounding wire 62 at the outer wheel 32a portion. The platform 90 may be provided with a tilting mechanism for tilting the constituent members of the electric arc furnace 1 such as the furnace shell 10 , so that the tapping of molten metal and the furnace shell 10 are removed from the platform 90 . The discharge of slag is facilitated.

The electric arc furnace 1 is provided with three grounding wires, namely, a furnace shell grounding wire 61, a furnace shell moving mechanism grounding wire 62, and a furnace roof moving mechanism grounding wire 63, but these are provided as independent grounding wires. For example, these three ground wires 61 to 63 are respectively connected to three ground electrodes buried in the ground at separate positions.

(Features of electric arc furnace)

As described above, in the electric arc furnace 1 according to the present embodiment, the positional relationship between the furnace shell 10 and the electrode 25 is that the furnace shell 10 is moved to the electrode ( 25) can be changed by rotating about it. By changing the positional relationship, the uniformity of melting and heating of the metal material in the furnace shell 10 can be improved. That is, as the electrodes 25 are arranged in a triangular shape around the central axis of the furnace shell 10 having a substantially cylindrical shape, hot spots adjacent to the electrodes 25 and prone to high temperatures and far away from the electrodes 25 and difficult to high temperatures. A cold spot is essentially created in the furnace shell 10 . However, by rotating the furnace shell 10 to change the positional relationship between the furnace shell 10 and the electrode 25 during the melting process of the metal material, the angular positions of the cold spot and the hot spot can also be appropriately changed and , the uniformity of melting and heating of metal materials can be obtained. From the viewpoint of sufficiently and necessary changing the respective positions of the cold spot and the hot spot, the rotation angle of the furnace shell 10 is preferably substantially in the range of 50° to 60° when the number of electrodes is three.

When performing arc discharge, an alternating current of several tens of kA flows to the electrode 25 inserted in the furnace shell 10 . This current may flow to the furnace shell moving mechanism 30 or the furnace roof moving mechanism 43 as a leakage current through the metal material in the furnace shell 10 , the furnace roof 20 , or the like. In addition, an induced current in the range of several amperes to several hundreds of amperes may flow from the surface of the furnace shell 10 to the steel shell. When this leakage current or induced current flows from the furnace shell 10 into a movable part such as the bearing of the furnace roof moving mechanism 43 or the furnace shell moving mechanism 30, the furnace shell moving mechanism 30 or the furnace roof moving Even when the mechanism 43 is in a fixed state, sparks may be generated in the movable portion. Accordingly, the smooth movement of the movable part may be interfered with, and unavoidable damage such as breakage of materials constituting the movable part may be caused.

However, in the electric arc furnace 1 according to the present embodiment, the furnace shell insulating member 51 is provided between the furnace shell 10 and the furnace shell moving mechanism 30, and the furnace shell 10 and the furnace shell moving mechanism ( 30) is electrically insulated between them. Further, in the furnace roof holding unit 40 , the furnace roof insulating member 52 is provided between the furnace roof support 41 and the furnace roof moving mechanism 43 . Accordingly, the furnace roof moving mechanism 43 is also electrically insulated from each of the furnace roof 20 and the furnace shell 10 in contact with the furnace roof 20 and its steel shell in the closed state of the furnace roof 20 . According to this arrangement, when an induced current or a leakage current flows in the furnace shell 10 , these currents are prevented from flowing in the furnace shell moving mechanism 30 and the furnace roof moving mechanism 43 . The insulating material constituting the furnace shell insulating member 51 and the furnace roof insulating member 52 is, for example, a JIS-H type insulator having high heat resistance, such as a laminate formed of a silicone resin and glass (silicon laminate material). can be

In the electric arc furnace 1, also, each component is independently grounded. That is, the furnace shell 10 is grounded to the furnace shell ground wire 61, the furnace shell moving mechanism 30 is grounded to the furnace shell moving mechanism ground wire 62 through the platform 90, and the furnace roof moving mechanism 43 ) is grounded to the furnace roof moving mechanism ground wire 63 . Therefore, even if dielectric breakdown occurs in the furnace shell insulating member 51 or the furnace roof insulating member 52, for example, by a high voltage applied to both ends thereof, the leakage current or the induced current flowing through the furnace shell 10 is It flows to the earth potential through the shell ground wire 61, and thus does not flow to the furnace shell moving mechanism 30 and the furnace roof moving mechanism 43.

In the electric arc furnace 1 , the bearing connecting wire 33 electrically connects between the outer wheel 32a and the inner wheel 32b of the bearing 32 of the furnace shell moving mechanism 30 . Accordingly, the outer wheel 32a and the inner wheel 32b maintain equipotentiality. Further, not only the outer wheel 32a is grounded by the furnace shell moving mechanism ground wire 62 through the platform 90 and the attachment base 34, but also the inner wheel 32b is grounded. As a result, current is prevented from flowing between the outer wheel 32a and the inner wheel 32b. Therefore, even if a leakage current or an induced current flowing in the furnace shell 10 flows in either one of the outer wheel 32a and the inner wheel 32b, this current flows through the other one of the outer wheel 32a and the inner wheel 32b. flow is prevented and sparks are prevented from occurring in a large area of the bearing 32 .

The bearing connection wire 33 is schematically illustrated in FIG. 3 as a wiring connection between the support frame 31 and the attachment base 34 . However, the correct method of attaching the bearing connecting wire 33 may be any one of the methods in which the outer wheel 32a and the inner wheel 32b of the bearing 32 are electrically connected to each other. One embodiment of such an attachment method is shown in Figures 4a and 4b. In this embodiment, brackets 31c made to have conductivity with the main body of the support frame 31 are provided in the substantially central portion of the support frame 31 in the height direction, respectively. A connecting rod 91 made to be conductive with the main body of the platform 90 stands on the platform 90, and each bracket 91a corresponds to a corresponding frame-side bracket 31c and is positioned at substantially the same height as the corresponding frame side bracket 31c. It is provided on the upper end of the connecting rod (91). Each connecting rod 91 is provided at a substantially central angular position of the movable range of the inner wheel 32b of the bearing 32 . One end of each bearing connecting wire 33 is connected to a corresponding support frame side bracket 31c, and the other end thereof is connected to a corresponding connecting rod side bracket 91a. Each bearing connecting wire 33 has a length sufficient to follow the entire movable range of the inner wheel 32b of the bearing 32 . The length of each bearing connecting wire 33 and the positions of the two brackets 31c and 91a corresponding to the length of each bearing connecting wire 33 drive the bearing 32 over the entire movable range of the inner wheel 32b. In order to do this, it is set in such a way that it is positioned above an obstacle (not shown) such as an essential unit attached to the driving unit provided on the platform 90 .

When the bearing connecting wire 33 is connected using the corresponding brackets 31c and 91a, the conductivity between the outer wheel 32a and the inner wheel 32b of the bearing 32 can be ensured with high reliability. In addition, when each bearing connecting wire 33 is made to have a length that can follow the entire rotatable range of the inner wheel 32b, each bearing connecting wire 33 is indicated by a solid line and a dotted line in Fig. 4A. As shown, excessive external force over the entire rotatable range of the inner wheel 32b can be prevented from being applied or damaged. In particular, as shown in Fig. 4B, the length of each bearing connecting wire 33 is set to be slightly longer so that each bearing connecting wire can remain bent without deformation over the entire rotatable range of the inner wheel 32b. In this case, it is possible to effectively prevent excessive external force from being applied or damaged to each of the bearing connecting wires 33 .

Further, each bearing connecting wire 33 is arranged above the plane of the platform 90 and also arranged over an obstacle (not shown) such as an essential unit attached to a drive unit provided on the platform 90 for driving the bearing 32 . In this case, each bearing connecting wire 33 can avoid interfering with the static object when the inner wheel 32b of the bearing 32 rotates. When a member acting as an obstacle to the bearing connecting wire 33 is provided in an area above the platform 90 passing through the bearing connecting wire 33 with the rotation of the inner wheel 32b, the bearing connecting wire 33 is When it is not arranged to grovel along the plane of the platform 90, but is arranged on the plane of the platform 90, preferably above the obstacle, it is possible to avoid the bearing connecting wire 33 from interfering with the obstacle. . Although it is desirable for the bearing connecting wire 33 to have a length capable of maintaining the bent state as described above, it is preferable that the length is set within the extent that the bent portion does not contact the obstacle. When each connecting rod 91 is provided at a substantially central angular position of the movable range of the inner wheel 32b, the bent state of the corresponding bearing connecting wire 33 excessively extends the corresponding bearing connecting wire 33 It can be easily ensured that it spans the entire movable range of the inner wheel 32b without having to do so.

As described above, the embodiments according to the present invention have been described in detail, but the present invention is not limited to the above-described embodiments and can be changed and modified in various ways without departing from the gist of the present invention. For example, the movement of the furnace shell is not limited to rotating (shaking) about the central axis of the furnace shell, and may be arbitrarily moved on the platform. Also, the furnace shell moving mechanism is not limited to using a bearing, and may be, for example, using a roller.

This application is based on Japanese Patent Application No. 2014-225148, filed on November 5, 2014 and Japanese Patent Application No. 2015-146743, filed on July 24, 2015, the contents of which are incorporated herein by reference do.

1: Electric arc furnace
10: raw shell
20: furnace roof
25: electrode
30: furnace shell movement mechanism
31: support frame
31c: bracket
32: bearing
32a: outer wheel
32b: inner wheel
33: bearing connection wire
34: attachment base
35: gear unit
40: low roof maintenance unit
41: furnace roof support
42: electrode support
43: furnace roof moving mechanism
51: raw shell insulating member (first insulating member)
52: low roof insulating member (second insulating member)
61: raw shell ground wire
62: furnace shell moving mechanism ground wire
63: furnace roof moving mechanism ground wire
90: platform (installation surface)
91: connection load
91a: bracket

Claims (6)

raw shell;
an electrode inserted into the furnace shell;
a furnace shell moving mechanism for supporting the furnace shell so as to be movable on an installation surface; and
a first insulating member electrically insulating between the furnace shell and the furnace shell moving mechanism;
The furnace shell moving mechanism includes a first portion fixed to the installation surface and a second portion fixed to the furnace shell and movable relative to the first portion,
the first part is electrically connected to the second part;
a connection wire electrically connecting the first part and the second part of the furnace shell moving mechanism;
and the connecting wire has a length capable of following the entire movable range of the second portion. delete delete According to claim 1,
The electric arc furnace, characterized in that the furnace shell and the furnace shell moving mechanism are independently grounded. 5. The method of claim 1 or 4,
a furnace roof covering the opening of the furnace shell;
a furnace roof moving mechanism for moving the furnace roof relative to the furnace shell; and
The electric arc furnace according to claim 1, further comprising a second insulating member that electrically insulates between the furnace roof moving mechanism and the furnace shell. 6. The method of claim 5,
The electric arc furnace, characterized in that the furnace shell and the furnace roof moving mechanism are independently grounded.

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