KR200310347Y1 - Height adjustment of electrode rod in electric furnace - Google Patents

Abstract

The present invention relates to an electrode height adjusting device of the electric furnace, and in particular, the fluid inside the fixed while fixed to the floor to be located directly below the electrode (2) taken out of the electric furnace (6) when the scraping of the electric furnace (6) (18) is completely filled, the piston 13 is built up and down between the upper and lower stoppers (15, 16), the upper and lower ends of the bypass pipe (17) to the upper and lower outer peripheral surface of the upper and lower limit stoppers (15, 16) Cylinders 14 which are each through-coupled; A seating container 10 installed at an upper portion of the cylinder 14 to move up and down elastically along the rod 12 coupled with the piston 13, and having a lower end of the electrode rod 2 mounted thereon; A cylinder (20) built in to be moved by the guide bar (19) coupled with the seating vessel (10), and one end of the flexible pipe (23) connected to an upper end thereof; It is connected to the other end of the flexible pipe 23 is fixed side by side to the level measuring case 27, and comparing the level of the fluid 22 filled in the cylinder 20 and the flexible pipe 23 to the seating container (10) It relates to an electrode rod height adjusting device of the electric furnace, characterized in that consisting of a level gauge 24 for measuring the height difference of the lower end of the electrode rod 2 seated on the).

Description

Electrode height adjusting device of electric furnace

The present invention relates to an electrode height adjusting device of the electric furnace, and more particularly to an electrode height adjusting device of the electric furnace that can accurately adjust the height deviation of the bottom end of the electrode using the scrap metal loading time of the electric furnace.

In general, the scrap metal of an electric furnace is melted by arc heat generated from three electrodes, and if the bottom heights of the three electrodes charged into the furnace do not coincide, the arc heat is incompletely generated due to the difference in impedance generated in each phase. The efficiency drops sharply and at the same time adversely affects scrap metal melting.

Therefore, in the related art, after the molten metal of the electric furnace 6 is tapped onto the tapping ladle as shown in FIG. 1, the bottom height of the electrode 2 is checked visually through the electric furnace work tool 5. You will decide whether to adjust the height.

At this time, when the naked eye height difference of the three electrodes (2) when judged by the naked eye is more than 30cm, the height of the electrode is adjusted.

Here, the conventional lower electrode height adjustment operation of the electrode 2, the operator climbs the electric furnace loop (4) and hooks the hook of the ceiling crane (1) to the ring (2-1) of the electrode (2) the operator on the ground operation panel The height of the lower end of the electrode is adjusted by using the ceiling crane 1 while opening the electrode clamp 3 by operating.

Then, when it is visually determined that the bottom height of the electrode 2 is matched through the electric furnace work tool 5, the electrode clamp 3 is closed again to fix the electrode, and the worker who climbs the electric furnace loop 4 When the hook hanger of the ceiling crane 1 is detached from the hook 2-1 of the electrode rod, the bottom height adjustment of the electrode rod is completed.

However, since the lower electrode height adjustment operation of the conventional electrode 2 is adjusted by the naked eye of the operator, the accuracy thereof is lowered, and the productivity of the operation is lowered because the adjustment operation is performed during the melting operation.

The object of the present invention is to provide a device for adjusting the height of electrode rods that can accurately adjust the height difference of the lower end of the electrode rods by using the load time of the electric furnace, increase the melting efficiency of the scrap metal, and improve the productivity of the work. There is this.

1 is a working state diagram showing the adjustment of the bottom height of a conventional electrode electrode;

Figure 2 is a cross-sectional view showing the electrode height adjustment device of the electric furnace according to the present invention,

Figure 3 is a working state diagram showing the working state of the electrode height adjustment device of the electric furnace according to the present invention.

<Description of the symbols for the main parts of the drawings>

1: ceiling crane 2: electrode 3: electrode clamp

4: furnace loop 5: work tool 6: furnace

7: cylinder 7-1: driven gear 8: motor

8-1: Drive Gear 9: Electrode Arm 10: Seating Container

11: compression spring 12: rod 13: piston

14: cylinder 15: upper and lower stopper 16: lower limit stopper

17: bypass tube 18: fluid 19: guide bar

20: cylinder 21: piston 22: fluid

23: flexible piping 24: level gauge 25: base

26: glass tube 27: level measuring case

In order to achieve the above object, the present invention is fixed to the floor so as to be positioned directly under the electrode rods taken out of the electric furnace when the steel is loaded into the furnace, the fluid is completely filled therein, and the piston is built up and down between the upper and lower stoppers Cylinders having upper and lower ends of the bypass pipe penetrated to the upper and lower outer peripheral surfaces of the upper and lower stoppers, respectively; A mounting container installed at an upper portion of the cylinder to move up and down elastically along a rod coupled with the piston, and having a lower end of the electrode rod mounted thereon; A cylinder which is built so that the piston is moved by the guide rod coupled with the seating container, and one end of the flexible pipe is connected to an upper end thereof; It is connected to the other end of the flexible pipe is fixed side by side in the level measuring case, it is composed of a level gauge for measuring the height difference of the lower end of the electrode seated in the mounting container by comparing the level of the fluid filled in the cylinder and the flexible pipe Provided is an electrode height adjusting device for an electric furnace.

The configuration of the present invention will be described with reference to the drawings.

Figure 2 is a cross-sectional view showing the electrode height adjustment device of the electric furnace according to the present invention, Figure 3 is a working state diagram showing the working state of the electrode height adjustment device of the electric furnace according to the present invention.

The electrode bar height adjusting device of the electric furnace according to the present invention is the electrode bar (2) fixed by the electrode clamp (3) while charging the scrap metal into the electric furnace (6) after removing the electrode bar (2) from the electric furnace (6) It is installed to adjust the height difference of the bottom.

That is, as shown in Figs. 2 and 3, three cylinders 14 are fixed to the installation bottom surface, and the three cylinders 14 are fixed side by side in accordance with the interval of the electrode rod 2 by each base 25. The inside is completely filled with the fluid 18, and upper and lower stoppers 15 and 16 are fixed to the inner circumferential surface so as to be spaced up and down.

At this time, the bypass pipe 17 is connected to the outer circumferential surface of the cylinder 14 so that the upper end thereof is located above the upper limit stopper 15, and the lower end thereof is positioned below the lower limit stopper 16. It is connected to the outer circumferential surface.

Here, the piston (13) embedded in the cylinder 14 to move up and down between the upper and lower stoppers (15, 16) has a lower end of the rod 12 penetrating to the center of the upper surface of the cylinder 14 in the center of the upper surface It is fixedly attached.

In addition, a conical mounting container 10 is fixedly attached to an upper end of the rod 12, and a compression spring 11 is coupled to the rod 12 between the mounting container 10 and the upper surface of the cylinder 14. The seating vessel is to move up and down elastic.

On the other hand, a cylinder 21 is built in the cylinder 20 installed in parallel with each seating container 10, and the piston 21 is coupled to the seating container 10 by a substantially U-shaped guide rod 19. It is.

Accordingly, when each seating container 10 is elastically up and down, the piston 21 is also moved up and down along the inner circumferential surface of the cylinder 20 by the guide bar 19.

At this time, one end of the flexible pipe 23 is connected to the upper portion of the cylinder 20, the level gauge 24 is connected to the other end of the flexible pipe 23, the cylinder 20 and the flexible pipe 23 ), The colored fluid 22 is filled over the level gauge 24, and the fluid level of the level gauge changes as the piston 21 moves up and down.

Here, a scale gauge 24 is installed on the level gauge 24 installed side by side in the level measurement case 27 installed at a position that can be easily checked by the operator, and a ruler is drawn to adjust the relative height deviation of the electrode 2 according to the level of the fluid 22. You will know exactly.

In addition, the glass tube 26 connected to the upper portion of the level gauge 24 is bent so that its upper end is downward to prevent the inflow of foreign substances.

Hereinafter, the operation of the present invention.

As shown in Figure 1, when loading the scrap metal into the electric furnace 6, the electrode 2 and the electric furnace loop 4 is moved to the scrap metal loading position.

That is, after lifting the electrode 7 out of the electric furnace 6 by raising the cylinder 7, the motor 8 is again operated to rotate the electrode 90 °, and then the cylinder 7 is gradually lowered. The lower end is inserted into the seating vessel 10 of Figs.

At this time, if the cylinder 7 is further lowered, the lower end of the electrode 2 presses the seating vessel 10 downward, and accordingly, the rod 12 fixed to the bottom surface of the seating vessel 10 is lowered. Since the piston 13 is fixed to the lower end of the rod 12, the piston 13 eventually descends along the cylinder 14, and at the same time, the guide rod 19 pulls the piston 21 downward.

In addition, as the piston 13 descends, the fluid 22 moves downward along the cylinder 20, thereby lowering the level of the fluid 22 of the level gauge 24.

Here, when the fluid 22 level of the level gauge 24 starts to move, the lowering of the cylinder 7 is stopped, and the lower level deviation of the electrode 2 is detected by comparing the fluid level of the level gauge 24. .

At this time, when the fluid level deviation of the level gauge 24 is 30 cm or more, arc heat generation of the electrode 2 becomes incomplete, thereby adjusting the height of the lower end of the electrode.

On the other hand, if you want to adjust the height of the lower end of the electrode 2, the electrode clamp (3) is opened at the same time, the electrode rod separated from the electrode clamp (3) will continue to push the seating container 10 by its own weight .

At this time, the lowering of the electrode rod 2 is prevented by the compression spring 11 and the fluid 18 in the cylinder 14, and the lowering of the electrode rod stops when the piston 13 reaches the lower limit stopper 16. .

Here, the heights of the lower ends of the three electrodes 2 are adjusted to the same height as the piston 13 is stopped by the lower limit stopper 16, which indicates that the level of the fluid 22 of the level gauge 24 is the same height. It can be confirmed as stopped by pointing.

Then, the electrode clamp 3 is closed to fix the electrode 2, and when the scraping of the electric furnace 6 is completed, the electrode rod and the electric furnace loop 4 are reattached to the electric furnace 6. Scrap metal melting will be performed.

On the other hand, the seating vessel 10 from which the electrode 2 is removed is raised by the elastic force of the compression spring 11, whereby the piston 13 is raised to the upper limit stopper 15, the piston 21 is guided It is pushed up by the rod 19.

The present invention can accurately adjust the bottom height deviation of the electrode using the scrap metal loading time of the electric furnace, improve the melting efficiency of scrap metal, and provide the effect of improving the productivity of the work.

Claims (1)

When the scrap metal of the electric furnace (6) is inserted into the bottom so as to be located directly below each of the electrode rods 2 taken out from the electric furnace (6), the fluid 18 is completely filled therein, the piston 13 is the upper and lower A cylinder (14) which is built so as to move up and down between the stoppers (15, 16), and the upper and lower ends of the bypass pipe (17) are respectively coupled to the upper and lower side outer peripheral surfaces of the upper and lower stoppers (15, 16); A seating container 10 installed at an upper portion of the cylinder 14 to move up and down elastically along the rod 12 coupled with the piston 13, and having a lower end of the electrode rod 2 mounted thereon; A cylinder (20) built in to be moved by the guide bar (19) coupled with the seating vessel (10), and one end of the flexible pipe (23) connected to an upper end thereof; It is connected to the other end of the flexible pipe 23 is fixed side by side to the level measuring case 27, and comparing the level of the fluid 22 filled in the cylinder 20 and the flexible pipe 23 to the seating container (10) The electrode rod height adjusting device of the electric furnace, characterized in that consisting of a level gauge (24) for measuring the height difference of the lower end of the electrode rod (2) seated on the).