KR100287759B1 - Electric furnace - Google Patents

Abstract

The present invention relates to an electric furnace, and in the past, mainly used a gas furnace for melting the molten melted, such a gas is required to have a separate means for the injection of gas and the discharge of waste gas, the installation volume is large and expensive and environmental There are disadvantages in that a waste gas treatment purifying means must be provided to prevent pollution, and heat leakage occurs along with the waste gas exhausted, thereby reducing heat transfer efficiency.

In order to solve this problem, the present invention is to install a plurality of supports along the rim to give the support while forming the appearance, and to fix the plate-shaped base on the support of a certain height from the bottom of the installation, mounted on the base upper surface inside It has a hollow rectangular water jacket so that the coolant flows through it, and loads the pole refractories along the outer edge of the water jacket, and secures a pair of side supports inclined to the support on the upper side of the pole jacket. Fixing the stair-shaped support beam on the inner side of the support, and directly below the support beam is provided with a plurality of heating elements installed across the furnace, and load the refractory brick from the upper side of the refractory to close the lower outer surface of the side support The roof is closed with the top of the inclinedly open top of the furnace and connected to the inside of the rear wall of the furnace. The invention hayeoseo install the blood melt supply means being that.

Description

Electric furnace

The present invention relates to an electric furnace, and more particularly, to an electric furnace used to extract lead silicate from a lead oxide and silica sand mixture by using a water jacket to reduce the amount of refractory refractory used to reduce manufacturing costs and to provide excellent durability. .

Generally, a furnace is an apparatus used for smelting or refining a metal or nonferrous metal, or extracting and refining a metal contained in ore or other raw materials.

In particular, lead silicate, which is used as a raw material for bulbs and frit glass of CRT tubes, is extracted from a mixture of lead oxide and silica sand, and is mainly produced by melting in a gas furnace.

Such gases include a combustion chamber for receiving the melted material to be supplied, a gas burner serving as a heat source for applying heat to the melted gas, a gas supply means for supplying gas to the gas burner, and waste gas generated by burning gas in the combustion chamber. It is configured to include a gas exhaust means for discharging.

Herein, the rotatable heat storage type is preferred for the gas burner because it uniformly transfers heat to the molten material.

For example, industrial furnaces as disclosed in Japanese Patent Laid-Open Nos. JP-A-1-222,102 and JP-A-4-101,191 have a heat storage device formed of a heat storage material and applied to clarify permeability to gas. And a duct portion communicating with the heat accumulator, the duct portion including an oxidant duct for passing an oxidant formed therein and an exhaust gas duct for passing exhaust gas generated from combustion (also, as another example, a Korean patent "Steel Heating Furnace" registered in Korean Patent No. 97-103, and "Apparatus and Method for Providing Uniform Heat Transfer to Surface" of Korean Patent No. 97-3645).

The oxidant duct has an oxidant passage therein for passing the oxidant, and the exhaust gas duct has an exhaust gas passage therein for passing the exhaust gas generated from combustion in the furnace. The heating of the oxidant is carried out through the heat accumulator heated by the exhaust gas by rotating the heat accumulator and the duct section with respect to each other.

The term oxidant as used herein generally refers to a gas containing oxygen atoms such as pure oxygen, nitrogen oxides, and a mixed gas containing oxygen gas such as air and oxygen enriched air.

However, in the case of the above-described gas furnace, a separate means for injecting the gas and exhausting the waste gas should be provided, which requires a large installation volume and high cost, and further includes a purification treatment means for waste gas treatment to prevent environmental pollution. There are disadvantages that must be made.

In addition, since heat is discharged from the exhaust gas exhausted, heat loss is generated to the extent that heat loss is reduced.

Particularly, when lead silicate is extracted from a mixture of lead oxide and silica sand, the specific gravity of lead in the molten material is large, and the bottom surface and sidewalls are eroded in the course of melting.

Therefore, in order to prevent such erosion, the bottom surface and sidewalls must be stacked with special refractory bricks, that is, refractory bricks (hereinafter referred to as "pole refractory materials") formed to have very small pores.

However, such electric pole refractories are expensive, and in general, the cost is high at the time of accumulation.

The present invention has been made to solve the problems that the prior art has not solved, and in extracting lead silicate which is a raw material of bulb and frit glass of CRT from metal or nonferrous metals, in particular of lead oxide and silica sand mixture. The purpose is to provide such an electric furnace with a small volume and relatively high thermal efficiency.

It is another object of the present invention to provide such an electric furnace that can be manufactured at a low cost and prevents erosion by melt even if the bottom and sidewalls of the furnace are not finished with expensive pole refractories.

This object of the present invention, in the electric furnace installed to constitute a furnace by the heating element of the alternating current electricity, a support base which is provided along the outer edge of the furnace to give a support force to the furnace while forming an appearance, and the installation floor to be supported by the support A plate-shaped base welded to the support at a predetermined height from the surface, a water jacket formed in a hollow rectangular shape mounted on the upper surface of the base and having a cooling water flowing therein, and along the edge of the water jacket A pole refractories loaded to form a bottom sidewall, a pair of side supports fixed to the support at an upper side of the pole refractories and opposed to each other at a distance from each other, and a support beam fixed stepwise to an inner surface of the side supports; , Such as a heater installed across the furnace directly below the support beam And a plurality of heating elements, refractory bricks loaded from the upper side of the main refractories to close the lower outer surface of the side support, an arcuate loop covering an upper surface inclined by the side support, and the rear wall of the furnace. It is achieved by configuring the melted water supply means which is installed to communicate with the inside of the furnace is installed to supply the melted water.

1 is a perspective view showing the overall appearance of an electric furnace according to the present invention;

Figure 2 is a perspective view showing in detail the configuration of the base of the electric furnace according to the present invention and the water jacket mounted on the upper surface,

3A to 3D are detailed views of the fixing structure of the water jacket according to the present invention, and an enlarged cross-sectional view of section A, B, C, and D of FIG.

4 is a perspective view showing a bottom surface of the electric furnace according to the present invention;

5 is an enlarged perspective view of part E of FIG. 4;

6 is a perspective view showing the installation state of the side wall and the upper surface of the electric furnace according to the present invention;

7a to 7b is a perspective view showing a support beam according to the present invention,

8 is a cross-sectional view showing in detail the coupling structure between the support beam and the loop cut along the line H-H of FIG.

9 is a perspective view showing the melted supply means according to the invention.

Explanation of symbols on the main parts of the drawings

100: support, 200: side support,

202: support beam, 300: base,

400: fireproof brick, 410: electric pole refractory material,

420: fireproof brick support, 430: melt outlet,

500: loop, 600: water jacket,

800: melted water supply means, 814: screw feeder,

900: heating element, 910: support.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment according to the present invention will be described in more detail.

1 is a perspective view showing the overall appearance of an electric furnace according to the present invention.

As shown in the figure, the electric furnace to form a plurality of supports along the edge of the furnace to give a support force to the furnace 100, the base 300 fixed by the support 100, and the base 300 A pair of side supports 200 which are formed to be inclined while being fixed to the supports 100, fireproof bricks 400 which are mounted to cover the lower outer surface of the side supports 200, and by the side supports 200. It consists of a loop 500 covering an inclinedly open top surface.

The support 100 is a frame constituting the overall appearance of the furnace as a column fixed to the bottom surface.

Therefore, since the support 100 should have a solid support force, it is preferable to zoom, such as H-beam made of steel.

On the other hand, the upper side of the support 100 is fixed a plurality of horizontal connecting rods 102 in the transverse direction of the support 100, a plurality of longitudinal connecting rods 104 are fixed along the longitudinal direction.

These connecting rods (102, 104) is to maintain a constant interval without the upper side of the support 100 to open inward or outward so that the support force is a constant action.

In addition, the support 100 is installed at regular intervals along the edge of the furnace.

The base 300 constitutes a bottom surface of the furnace, and the water jacket 600 described later is mounted on the top surface.

In addition, the base 300 is a rectangular support plate is installed spaced apart from the lower end of the support 100 by a predetermined height, it is generally provided that the welding is fixed to the support 100.

The base 300 is further extended from the rear end formed by the support 100 to the appearance of the furnace.

This is to install a screw feeder 814 to be described later that is a supply means for supplying the molten material to the inside of the furnace.

The side support 200 is a heating element (not shown), which is a heat source of the furnace, is installed and is inclined in consideration of the shape of the supplied melted material to be melted from the surface of the melted material supplied into the furnace, but the total amount This is to make it melt uniformly.

Therefore, one end of the side support 200 is fixed to the front end side of the base 300 and the other end is fixed to the upper end of the support 100 placed in the last end of the support 100 forming the appearance of the furnace.

In addition, the side support 200 is provided with a pair to face each other at a distance to each other, the inner side is formed with a plurality of stepped support beams 202, respectively.

Refractory brick 400 is a brick having a porous heat resistance to form an inner space of the electric furnace for accommodating the molten material, it is also a means for thermally blocking the interior and exterior of the electric furnace.

To this end, the outer surface of the refractory brick 400 is insulated.

The roof 500 is arched as shown to cover the upper surface of the lower edge of the side support 200 by the firebrick 400 so as to completely seal the interior space of the furnace. give.

Accordingly, both ends of the loop 500 are mounted and fixed to each support beam 202 fixed in a stepped manner to the inner side surface of the side support 200.

Thereafter, the upper surface is insulated with a separate heat insulating material similar to the outer surface of the firebrick 400.

The external structure of an electric furnace is formed by the structure as mentioned above.

Figure 2 shows in detail the configuration of the base 300 of the electric furnace according to the present invention and the water jacket 600 mounted on the upper surface.

As shown in the figure, the water jacket 600 is divided into approximately three and placed on the base 300. This is to provide ease in replacing the water jacket 600.

The water jacket 600 is formed in the same size and shape, respectively, the inside is formed in an empty rectangular parallelepiped, both sides of the lower end of each of the side flange 610 having a bolt hole 612 at the edge portion is extended to the outside Is formed.

In addition, the water jacket 600 has a discharge port 630 is formed on one side of the upper surface and the supply port 620 is formed on one side thereof.

Thus, the cooling water is supplied to the empty space therein through the supply port 620 and then discharged through the discharge port 630 to cool the upper surface of the water jacket 600.

As such, the supply of the cooling water flowing through the water jacket 600 to the lower side and discharged from the upper side is to maximize the contact area between the inner surface of the water jacket 600 and the cooling water to increase the cooling effect.

3A to 3D show the fixing structure of the water jacket 600 according to the present invention in detail, and are respectively enlarged by cross-sectional processing of A, B, C, and D portions of FIG. 2.

3A, 3C, and 3D, a fixing piece 120 is provided to fix the support 100 while supporting a lower end of the side flange 610 of the water jacket 600.

The fixing piece 120 is formed to be bent in a 'b' shape, the bent one side surface is in close contact with the support 100 is fixed with a plurality of bolts 614 and the other side surface flange 610 The bottom surface of the) is placed in close contact and then fixed by the bolt 614.

Therefore, the water jacket 600 is installed on the base 300 or removed for replacement is very easy.

In addition, the water jacket 600 has a hollow portion 604 having a hollow inside, and the hollow portion 604 is a passage through which cooling water flows.

In addition, a supply port 620 is provided on one side of the water jacket 600 so as to be connected to a separate cooling water supply means so as to communicate with the hollow part 604, and an outlet opening connected to the cooling water discharge means on the other upper surface thereof. 630 is provided.

In FIG. 3B, the water jacket 600 includes a space retaining pin 608 provided at a portion to prevent the upper surface of the hollow portion 604 from being warped or distorted due to the load of the molten material.

The gap maintaining pin 608 is a rod-shaped rod, and both ends thereof are fixed to the upper and lower end surfaces of the hollow part 604 by welding.

4 is a perspective view showing a bottom surface of the electric furnace according to the present invention.

As shown in the drawing, the electric pole refractory 410 is loaded along the edge of the water jacket 600.

As described above, the electric pole refractory brick 410 is a refractory brick having very small pores, and is a refractory brick that is very resistant to erosion caused by the flow of a melt having a high specific gravity.

That is, they do not easily erode.

The electric pole refractory 410 is loaded only one stage at the bottom of the furnace. For it is very expensive.

In addition, a melt discharge port 430 is formed at the front end of the furnace to allow the accumulated melt to flow out to the outside of the bottom of the furnace, that is, the water jacket 600.

On the other hand, the auxiliary support piece 130 is fixed to the support 100 to correspond to the projecting height of the electric pole refractory 410 loaded on the water jacket 600.

The auxiliary support piece 130 is formed in the same shape as the fixing piece 120 described above.

Further, a plurality of long rod-shaped square bars are mounted on the upper surface of the auxiliary support piece 130 to form a firebrick support 420.

The firebrick support 420 is provided on all three surfaces except the front of the furnace.

FIG. 5 is an enlarged perspective view of part E of FIG. 4 and illustrates an anti-rolling means that supports the outer refractories 410 from the outside so as not to be pushed outward.

The anti-rolling means is a push rod 450 for closely supporting the outer surface of the electric pole refractory 410, the operating rod 452 is fixed to the push rod 450 to move the push rod 450, and the operation A fastener 454 fixed to the support 100 to support the rod 452 to move, and an adjustment 456 is installed on one end of the fastener 454 to adjust the movement width of the operating rod 452 It consists of.

The rod 450 is a crutch for preventing the pole refractories 410 are pushed out of the furnace in each direction. Such a push rod 450 is preferably formed to be bent in a 'V' shape and installed so that the opened surface thereof is in contact with the upper and lower ends of the pole refractories 410.

The operating rod 452 is fixed to the rod 450, it is preferable to weld fixed to the bent portion of the 'V' shape, it is also preferable to form a thread other than the welded fixed portion.

Fixture 454 is a hollow cylindrical body for guiding the operating rod 452, welding to the support 100 in a state parallel to the operating rod 452 so that the operating rod 452 can be inserted. It is fixed.

The adjuster 456 is rotatably fixed to one end of the fixture 454.

In addition, a screw thread corresponding to the operating rod 452 is formed on the inner circumference of the adjusting hole 456.

Therefore, the control rod 456 is rotated clockwise or counterclockwise to be engaged with it so that the working rod 452 is advanced back and forth so that the push rod 450 can be in close contact with the electric pole refractory 410. do.

6 is a perspective view showing the installation state of the side wall and the upper surface of the electric furnace according to the present invention.

As shown in the figure, the refractory brick 400 is loaded on the refractory brick support 420 to form an outer wall of the electric furnace.

The refractory brick 400 is loaded from the upper side of the electric pole refractory 410 stacked in one step on the outer edge of the furnace bar, the side support 200 fixed with a predetermined inclination angle on the inner surface of the support 100 It is loaded underneath.

Therefore, it is loaded inclined from the front end of the furnace toward the rear end. The inclined loading from the front end of the furnace toward the rear end is because molten material is supplied from the rear side of the furnace.

On the other hand, the molten material supply means 800 for supplying the molten material to the rear of the furnace is installed.

The melted water supply means 800 is fixed to the upper surface of the base 300 extending from the rear of the furnace.

On the other hand, the top of the furnace is covered by an arcuate loop 500.

The roof 500 may be made of the same refractory brick as the refractory brick 400 forming the side walls of the furnace.

In addition, the loop 500 is supported by the support beam 202 fixed to the side support 200 is configured.

In addition, a heating element 900 is provided directly below the roof 500, and the heating element 900 is a heater dissipating heat, and these heaters are inclined in a stepped shape, and a plurality of heating elements are provided.

Both ends of the heating element 900 are supported by the support 910, and the support 910 is fixed to each other by welding to the support 100.

In addition, the support 910 is preferably installed in the same number as the support 202 directly below the support 202.

To this end, although not illustrated in the drawings, the frame is first fixed and a refractory brick is loaded on the frame to form the loop 500. Thereafter, the frame is separated to form the upper surface of the furnace.

7A and 7B illustrate a support beam 202 for forming such a loop 500, and particularly, a cut structure along the HH line of FIG. 6 to detail the coupling structure between the support beam 200 and the loop 500. 8 is shown.

As shown in the figure, the support beam 202 is welded to the support 100, the welding portion 202a, the upper end of the welded portion 202a is vertically bent after the upper support portion 202b formed and, The lower end of the weld portion 202a is vertically bent after extending in the same direction as the upper support portion 202b and the lower support portion 202c is formed and is fixed to the lower surface of the lower support portion 202c and extends longer than that. It consists of the extended support part 202d.

The support beam 202 shown in FIG. 7A is used for the inclined portion of the sidewall of the furnace, and the support beam 202 'shown in FIG. 7B is formed in the same shape as the support beam 202, but the side thereof is Only the direction length is formed longer.

The fixing part 502 of the refractory bricks constituting the loop 500 is inserted and fixed into the space formed by the upper and lower support parts 202b and 202c and the welding part 202a of the support beam 202. The connection part 504 is loaded in connection with 502, and a substantial upper portion of the middle of the furnace is connected with both connection parts 504 so that the first placing part 506 is loaded in an arc shape (or a dome shape).

Thereafter, the first mounting part 506 covers the upper surface of the first mounting part 506 from one side to the other side of the upper surface between the fixing part 502 and the connection part 504, and the second mounting part 508 is stacked one more time.

In addition, the upper support portion 202b of the support beam 202 and the upper surface of the fixing portion 502 from one side to the other side of the cover along the second mounting portion 508 and the third mounting portion 510 again The layers are stacked one by one to form the final loop 500.

And, as described above, the support 910 is welded and fixed to the support 100 in the lower side of the support beam 202, the heating element 900 supported by the support 910 is installed. .

The support beam 202, the support 910, the heating element 900 and the loop 500 is installed in a stepped shape along the longitudinal direction of the side support 200.

In addition, as described above, when the side wall and the upper surface of the furnace are closed, the outer surface of the furnace is closed with a heat insulating material to prevent heat loss inside the furnace as much as possible.

9 is a perspective view showing the melted supply means 800 according to the present invention.

As shown in the figure, the melted supply means 800 includes a drive motor 802 that is a driving means, a fixing member 806 that fixes the drive motor 802, and a power transmission of the drive motor 802. A drive shaft 810 driven by the drive shaft, a screw feeder 814 fixed to the drive shaft 810, and a supply pipe 816 configured to receive the screw feeder 814 and communicate with the inside of the furnace on the rear wall of the electric furnace. It is composed.

The drive motor 802 and the drive shaft 810 are installed to transmit the power of the drive motor 802 by the power transmission means, for example, is connected by such as a chain 804.

In addition, a support bearing 808 is installed at the upper end of the fixing member 806 to smoothly rotate the drive shaft 810.

The screw feeder 814 is formed such that the inlet side into which the molten material is introduced maintains a dense spacing, and the screw is formed and maintains a sparse spacing without dense toward the outlet side.

Therefore, it is possible to achieve easy discharge to the outlet side while sucking and blending the melted material at a uniform speed.

This is because the place where the melted water flows is a large amount is introduced at once, and a large load is instantaneously, and because a certain amount of the inflow is discharged at the outlet side, the load is relatively small compared to the inlet side.

The supply pipe 816 is provided with a suction inlet 812 for suctioning the molten material on one side, the suction port 812 is formed in a funnel shape to guide the molten material easily into the supply pipe 816 A separate hopper is fitted on top of it.

When the molten material is supplied into the electric furnace by the molten melt supply means 800 to the electric furnace according to the present invention having such a configuration, the molten melt is accumulated in the furnace while forming a substantially triangular shape.

When a certain amount of melted material is accumulated, the heating element 900 is operated to melt the melted material. At this time, since the melted material is loaded in a triangular shape as described above, the heating element installed at an approximately horizontal and inclined angle ( Melting proceeds gradually from the surface of the melted material by the heat generated in 900, and the molten liquid flows to the bottom of the furnace.

At the same time, the coolant flows through the water jacket 600 so that the melt liquid flowing down to the bottom of the furnace is instantaneously cooled.

At this time, some of the melt is rapidly cooled to adhere to the surface of the water jacket 600 to form a coating layer.

When such a series of processes are performed, the coating layer has a thermal insulation function to some extent, which inhibits rapid cooling of the melt, and thus the melt moves to the melt discharge port 430 provided at the tip of the furnace along the bottom surface.

In this process, the melt has a constant speed and comes into contact with the electric pole refractory 410 loaded along the outermost edge of the furnace.

However, since the pole refractory 410 is not eroded well, it is discharged to the outside through the melt outlet 430 in a state having a certain flow rate.

On the other hand, when it is determined that the replacement of the internal parts or the peripheral parts due to the aging of the electric furnace as described above is necessary, the arcuate loop 500 constituting the upper part of the furnace does not need to be replaced. This makes it easy to replace at low cost.

As described above, the present invention can effectively melt the melted material with a small volume, unlike the conventional gas furnace, thereby providing an effect of reducing the production cost.

In addition, the electric furnace of the present invention does not require a separate environmental purification device for the waste gas treatment to be provided in the conventional gas furnace, it is simple to install and easy to work, and minimizes the heat loss emitted with the waste gas, the heat transfer efficiency is maximized effect Also provides.

In addition, it provides an effective and cost effective solution to the problem of eroding the bottom and sidewalls as the melt flows down.

Claims (3)

In an electric furnace installed to constitute a furnace by the heat of direct current or alternating current electricity, And the support 100 is installed along the outer edge of the furnace to give a support force to the furnace while forming an appearance, A plate-shaped base 300 welded and fixed to the support 100 at a predetermined height position from the installation bottom surface to be supported by the support 100; A water jacket 600 mounted on an upper surface of the base 300 and formed in a hollow rectangular shape to allow the cooling water to flow therethrough; An electric pole refractory material 410 loaded along the edge of the water jacket 600 to form a bottom sidewall of the furnace; A pair of side supports 200 which are fixed inclined to the support 100 at an upper side of the pole refractories 410 and opposed to each other at a distance from each other; A support beam 202 fixed to the inner side of the side support 200 in a step shape; A plurality of heating elements 900 such as heaters installed across the furnace directly below the support beam 202, Refractory brick 400 is loaded from the upper side of the pole refractories 410 to close the lower outer surface of the side support 200, An arcuate loop 500 covering the upper surface inclinedly opened by the side support 200; An electric furnace, characterized in that the molten material supply means 800 is installed to communicate with the inside of the furnace on the rear wall of the furnace is installed to supply the molten material. The electric furnace of claim 1, wherein the water jacket (600) is formed such that cooling water flowing through the inside of the water jacket (600) is supplied from the lower side and discharged upward. According to claim 1, wherein the melted supply means 800 is a drive motor 802 as a drive means, a fixing member 806 for fixing the drive motor 802, and the power transmission of the drive motor 802 The supply shaft 810 is driven by the drive shaft 810, the screw feeder 814 fixed to the drive shaft 810, the screw feeder 814 is installed to communicate with the interior of the furnace on the rear wall surface of the electric furnace Electric furnace, characterized in that consisting of.