KR20010110231A - crucible type electrical resistance furnace - Google Patents

Abstract

The present invention relates to a crucible-type resistance electric furnace, the purpose of which is that the insulating ceramic and the refractory ceramic is made of porous material and the semicircular heater installation groove is provided on the inner wall of the refractory ceramic, which is excellent in heat insulation and insulation effect In addition to minimizing the thickness of the heat is emitted from the heating heater is uniformly radiated in all directions.

The present invention is provided with a heat insulating ceramic 134 and a refractory ceramic 133 made of porous on the inner wall surface of the case 10, the inner surface of the refractory ceramic 133 has a predetermined interval horizontally from the bottom to the upper half-circular A wall 13b having a heater installation groove 135 formed therein; A crucible 12 placed on the crucible base 11b provided at the center bottom of the case 10 and spaced apart from an inner surface of the wall 13b to have a predetermined internal space; The wall 13b has a plurality of rod-type heating heaters 14 which are installed in a stacked shape by penetrating a space outside the crucible 12 and are provided for each waveform entering the inner wall surface of the wall 13b. It is a crucible type resistance electric furnace.

Description

Crucible type electrical resistance furnace

The present invention relates to a crucible-type resistance electric furnace, and more particularly, the insulator and the refractory material are made of porous material, and the inner wall is corrugated, so that the heat dissipation and thermal insulation effect is excellent, and the heat emitted from the heating heater is uniformly radiated in all directions. Relates to a resistance electric furnace.

In general, metal melting furnaces with relatively low dissolution capacities include crucible furnaces, reflecting furnaces, electric furnace cupolas, and the like. Divided.

As shown in FIG. 1A, the crucible 12 is placed on the crucible support 11a at the bottom of the center, and the refractory brick 131 and the heat insulating brick 132 have a hollow part 13 so that the wall 13a is formed. A plurality of rod-type heating heaters 14 were installed in the wall 13a in a stacked shape through the space between the outer surface of the crucible 12 and the firebrick 131.

As the resistive electricity as described above, the heat generated from the heat generating portion and the heat generated from the heat generating portion 14 when the power is supplied to the rod-type heating heater 14 are absorbed by the firebrick 131 and the heat insulating brick 132. Since the melted heat is transferred to the crucible 12 by the heat dissipated, the melted melt inside the crucible 12 is dissolved.

However, as the resistance electric furnace as described above, the refractory brick 131 and the insulating brick 132 are standardized so that the thickness of the wall 13a is minimized to 23 cm or more. There was a problem that transportation and installation are difficult. In addition, the refractory brick 131 that can be used at more than 1300 ℃ is so expensive that the production cost is increased and equipment cost burden.

In particular, the inner surface of the refractory brick 131 of the wall 13a is formed flat, so that the rod-type heating heater 14 absorbs heat generated therefrom and the refractory brick 131 and the heat insulating brick 132 absorb the heat. Since the heat dissipated is intensively applied to one surface of the rod-type heating heater 14, there is a problem that damage to the rod-type heating heater 14 is likely to occur.

Unlike the resistance electric furnace described above, the heavy oil passage is a refractory brick 131 and a heat insulating brick 132 so that the crucible 12 is placed on the crucible support 11a at the bottom of the center and has a hollow portion on the outside thereof as shown in FIG. 1B. The wall 13a is formed, and the burner 15 in which the flame is radiated toward the crucible support 11a is installed at the lower end of the wall 13a.

When the heavy oil passage is operated by the burner 15, and the flame is radiated to the crucible support 11a, the flame rises upward along the outer surface of the crucible 12 and hits the upper end of the wall 13a to be charged into the crucible 12. It hits the top of the melt again and then flies to the atmosphere.

Since the flame or heat of the burner 15 collides with the upper end of the crucible 12, the melted melt in the crucible 12 is dissolved from the upper end, and thus stirring is not performed well. Therefore, there is a closed end that must be forcibly stirred using a separate device.

In addition, since the flame reaches the inside of the upper end of the crucible 12 and oxidizes with the dissolved metal, it is scattered, causing a loss of molten material and a problem of easily causing pollution by incomplete combustion of oil.

And high frequency induction furnace is installed induction coil on the outer surface of the crucible, which has a high noise and power loss in the process of inducing the current at high frequency, and the stirring is rapid due to the magnetic field generated during high frequency induction. When used immediately, there is no problem, but if the molten metal is left in operation for a long time due to the characteristics of the high frequency induction furnace, the hydrogen (H ₂ ) gas penetrates and causes the bubble phenomenon. There was a problem that changed.

An object of the present invention has been researched and developed to solve the conventional problems as described above, the insulating ceramic and refractory ceramic is made of porous material and the semicircular heater installation groove is provided on the inner wall of the refractory ceramic, the heat insulating and thermal insulation effect It is excellent in that it is possible to minimize the thickness of the insulating material and the refractory material, as well as to provide a crucible-type resistance electric furnace so that the heat emitted from the heating heater is uniformly radiated in all directions.

Figure 1a is a cross-sectional view showing a conventional crucible-type resistance electric furnace,

Figure 1b is a cross-sectional view showing a conventional crucible heavy oil passage,

2 is a cross-sectional view showing a crucible resistance electric furnace according to the present invention;

3 is a cross-sectional view taken along the line A-A of FIG.

Figure 4 is a detailed cross-sectional view showing an excerpt of the wall portion that is the main part of the present invention.

<Explanation of symbols for main parts of drawing>

10: case 11a, 11b: crucible support 12: crucible

13a, 13b: wall 14: rod-type heating heater 15: burner

16: outlet 17: lid 18: cylinder

133: refractory ceramic 133a: split ceramic 133b: refractory ceramic mortar

134: adiabatic ceramic

In order to achieve the above object, the present invention is provided with a heat-insulating ceramic and a refractory ceramic made of porous on the inner wall surface of the case, the inner surface of the refractory ceramic has a predetermined interval horizontally from the bottom to the top of the semi-circular heater installation groove Formed wall; A crucible placed on the crucible support provided at the bottom center of the case and spaced apart from the inner surface of the wall and having a predetermined internal space; The crucible resistance electric furnace is installed in the wall through a space outside the crucible is provided in a stacked shape and a plurality of heating heaters are provided for each waveform entering the inner wall surface of the wall.

The crucible support is formed in three or more types of struts, and a discharge port is formed at the bottom of the case so as to be discharged even if the melt leaks from the crack of the crucible.

The upper end of the case and the crucible may be closed with a porous refractory ceramic so as to prevent heat loss and foreign substances generated from the heating heater to be introduced into the space of the crucible and the wall.

EMBODIMENT OF THE INVENTION Hereinafter, the crucible-type resistance electric furnace of this invention is demonstrated in detail based on an accompanying drawing.

Figure 2 is a cross-sectional view showing a crucible-type resistance electric furnace according to the present invention, Figure 3 is a cross-sectional view taken along the line A-A of Figure 2, Figure 4 is a detailed cross-sectional view showing an excerpt wall portion of the present invention.

As shown in the figure, a wall 13b is provided on the inner wall surface of the case 10, and the wall 13b is made of porous refractory ceramic 133 and adiabatic ceramic 134, and is formed of the refractory ceramic 133. A semicircular heater installation groove 135 is formed on the inner wall surface with a predetermined interval horizontally from the bottom to the top. At the bottom of the center of the case 10, a crucible support 11b of three or more types of struts is provided and spaced apart from the inner surface of the wall 13b on the crucible support 11b to have a predetermined internal space. Is installed.

The refractory ceramic plate 135 of the wall 13b is made of alumina (Al ₂ O ₃ ) and the heat insulating ceramic plate 136 is alumina (Al ₂ O ₃ ) and silicon oxide (SiO ₂ ) is mixed in a predetermined ratio will be. The insulating ceramic plate 136 may be provided in two layers with different mixing ratios of alumina (Al ₂ O ₃ ) and silicon oxide (SiO ₂ ).

The wall 13b has a plurality of rod-type heating heaters 14 installed in a shape stacked through the outer space of the crucible 12, and an installation position of the rod-type heating heaters 14 is located inside the wall 13b. Each waveform entering the wall must be positioned. The reason is that the heat emitted from the exothermic heater 14 and the heat absorbed by the porous refractory ceramic 133 and the adiabatic ceramic 134 are radiated uniformly in all directions. When uniformly radiated in this way, since it is not concentrated on one surface of the rod-type heating heater 14, the damage of the rod-type heating heater 14 is prevented.

The wall 13b is made of porous refractory ceramic 133 and adiabatic ceramic 134, so as the internal temperature of the wall 13b increases, the air in the refractory ceramic 133 and the insulating ceramic 134 expands. It is cut off from the outside and thus it is possible to obtain an improved thermal insulation effect.

The refractory ceramic 133 of the wall 13b may be provided as a split ceramic 133a formed by dividing it into one pitch of the heater installation groove 135 having a semicircular shape as shown in FIG. 5. In this way, when the divided ceramics 133a are provided, the divided ceramics 133a may be stacked on the inner side of the adiabatic ceramics 134 forming the wall 13b to facilitate the work.

The upper ends of the case 10 and the crucible 12 may prevent heat loss generated from the rod-type heating heater 14 and prevent foreign matter from entering the space between the crucible 12 and the wall 13b. The porous refractory ceramic mortar 133b is closed.

At the bottom of the case 10, a discharge port 16 is formed to discharge the internal space without accumulating the melt even if the melt leaks in the crack of the crucible 12.

A lid 17 is rotatably installed around one pin to cover the top of the crucible 12 and the lid 17 is installed to be opened and closed by a cylinder 18 at an upper end of the case 10. have.

In the crucible-type resistance electric machine of the present invention configured as described above, first, the cylinder 18 is operated to open the lid 17, charge the molten material to be melted, and then operate the cylinder 18 again to operate the lid 17. After closing, power is applied to the both ends of the bar-shaped heating heater 14 outside the wall 13b by a controller (not shown).

In this way, when power is applied to each of the rod-type heating heaters 14, the heat generating portion of the rod-type heating heaters 14 generates heat, and the heat generated in this way heats the air in the inner space and at the same time the crucible 12 and the fireproofing. It is absorbed into the ceramic 133 and the adiabatic ceramic 134.

After absorbing the heat of the rod heater 14 to a certain degree, the crucible 12 is raised to a predetermined temperature by the heat radiated toward the internal space and the heat generated from the rod heater 14, Will be maintained.

At this time, the insulating ceramic 134 and the refractory ceramic 133 of the wall 13b are formed in a waveform so that the heat emitted by the refractory ceramic 133 and the insulating ceramic 134 is radiated uniformly and radiated in all directions. It is possible to obtain a predetermined temperature within time, and heat is also not concentrated locally on the rod-type heat heater 14, thereby protecting the rod-type heat heater 14.

In addition, since the insulating ceramic 134 and the refractory ceramic 133 of the wall 13b are porous, as the temperature increases, the insulating ceramic 134 and the refractory ceramic 133 push the air to the outside, so that the inside is close to a vacuum, thereby minimizing heat loss.

In particular, since the upper part of the wall 13b and the crucible 12 in the case 10 are blocked, and the discharge port 16 is formed at the bottom of the case 10, the heat-insulating ceramic 134 and the refractory forming the liquid 13b are fireproof. Heat radiated from the rod-type heating heater 14 as well as heat radiated from the ceramic 133 is discharged to the atmosphere only through the discharge port 16 at the bottom of the case 10, and the lower part of the crucible 12 and the crucible support 11b. Since the rod-shaped heating heater 14 is more densely installed on the wall 13b in the outer position than the upper part of the crucible 12, the temperature of the lower part of the crucible 12 is higher than the upper part of the crucible 12.

Therefore, as such conditions (atmospheres) are continuously maintained, the molten material in the crucible 12 melts while the lower end portion of the crucible 12 first melts and gradually rises to the upper portion thereof. The molten melted melt in the crucible 12 is circulated and agitated by natural convection so that it maintains a uniform temperature at all times and prevents segregation.

As described in detail above, the crucible resistive electric furnace of the present invention has a semicircular heater installation groove formed on the inner wall of the refractory ceramic, so that the heat absorbed by the wall is radiated uniformly in all directions, and thus the predetermined temperature within the shortest time. There is a unique effect to protect the heating heater because the heat is not concentrated locally in the heating heater.

In addition, since the insulating ceramic and the refractory ceramic of the wall are made of porous material, the internal air is pushed to the outside as the temperature increases, so the inside is close to a vacuum, thereby minimizing heat loss.

In addition, since the temperature of the lower portion is higher than the upper portion of the crucible, the molten metal in the crucible is circulated and agitated by natural convection, thereby maintaining a uniform temperature at all times and having a unique effect of preventing segregation.

Claims (5)

On the inner wall of the case 10 is provided a heat insulating ceramic 134 and a refractory ceramic 133 made of porous, and the semi-circular heater is installed on the inner surface of the refractory ceramic 133 horizontally from the bottom to the top A wall 13b in which the groove 135 is formed; A crucible 12 placed on the crucible base 11b provided at the center bottom of the case 10 and spaced apart from an inner surface of the wall 13b to have a predetermined internal space; The wall 13b has a plurality of rod-type heating heaters 14 which are installed in a stacked shape by penetrating a space outside the crucible 12 and are provided for each waveform entering the inner wall surface of the wall 13b. Crucible-type resistance electric The method of claim 1, wherein the upper end of the case 10 and the crucible 12 prevents heat loss and foreign matter generated from the rod-type heating heater 14 into the inner space of the crucible 12 and the wall 13b. Crucible-type resistance electric furnace, characterized in that closed by porous refractory ceramic mortar (133b). The crucible resistance electric furnace according to claim 1, wherein the crucible support (11b) is formed in three or more types of struts. The crucible resistance electric furnace according to claim 1, wherein a discharge port (16) is formed at the bottom of the case (10) so as to be discharged even if the melt leaks from the crack of the crucible (12). The crucible-type resistive electric machine according to claim 1, wherein the refractory ceramic 133 of the wall 13b is formed of a split ceramic 133a formed by dividing it into one pitch of a semicircular heater installation groove 135. in.