KR100759311B1 - Furnace with easy removable refractory - Google Patents

Abstract

A melting furnace with easily removable refractories is provided to remove the refractories from the melting furnace easily and restrain dust from being generated on a workplace accordingly by forming a separating element between a coil cement and refractories in the melting furnace, thereby preventing reciprocal adhesion of the coil cement and the refractories. A melting furnace(100) with easily removable refractories comprises: a melting furnace metal case(110) of which an upper part is opened, and which is formed in the form of a vessel; a coil cement(120) adhered to an inner surface of the melting furnace metal case; refractories(130) formed on an inner side of the coil cement; and a separating element(140) formed between the coil cement and the refractories to prevent the coil cement and the refractories from being adhered to each other, wherein the separating element includes a rock wool fiber. The melting furnace with easily removable refractories further comprises: a gate(160) opening or closing a through hole formed in the bottom of the melting furnace metal case; and a plate(150) formed on an inner bottom face of the melting furnace metal case to open or close the through hole.

Description

FURNACE WITH EASY REMOVABLE REFRACTORY

1 is a cross-sectional view showing the internal structure of the crucible induction melting furnace according to the prior art.

2 is a cross-sectional view showing the internal structure of the crucible induction melting furnace according to an embodiment of the present invention.

3 is a conceptual diagram showing a refractory dismantling process for the melting furnace of FIG.

<Explanation of symbols for main parts of the drawings>

10: Melting Furnace 11: Melting Furnace

12: coil cement 13: refractory

100: melting furnace 110: melting furnace

120: coil cement 130: refractory

140: separating element 150: plate

160: gate 170: hydraulic cylinder

The present invention relates to a melting furnace, and more particularly to a melting furnace that is easily dismantled refractory to dismantle the refractory of the melting furnace to thereby suppress the generation of dust in the workplace.

A melting furnace is a furnace manufactured for the purpose of heating and dissolving a solid material above the melting point, and melting furnaces of various types such as melting furnaces, crucible furnaces, electric furnaces, and reflection furnaces are used depending on the type of heating apparatus.

This melting furnace requires a lot of energy to heat the solid material, and also shows a lot of differences in energy efficiency according to the type of heating device, recently, the energy efficiency is excellent and the automation and The use of low frequency and high frequency induction melting furnaces, which have good effects such as productivity improvement, is increasing.

Induction melting furnaces can be divided into crucible type and channel type according to their structure. Generally, crucible type is used for low frequency, channel type, low frequency and high frequency.

1 is a cross-sectional view schematically showing the internal structure of the crucible induction melting furnace according to the prior art.

The melting furnace 10 has a cylindrical shape with an open top, and a coil cement 12 and a coil cement 12 attached to an inner side of the melting furnace shell 11 and the melting furnace shell 11 that maintain the overall structure of the melting furnace 10 at the outermost part. It is configured to include a refractory 13 attached to the inside of).

The coil cement 12 is formed by applying heat-resistant cement with a heating coil (not shown) inserted therein. When the heating coil is connected to an electrode terminal and an alternating current is supplied to the heating coil, a conductor is induced by an electromagnetic induction action. Induction current is generated in the furnace and the inside of the furnace is heated.

The refractory material 13 is selected in relation to the temperature, properties, and the like of the solid material to be dissolved. The refractory material 13 is a material having high refractory properties such that thermal deformation does not occur even at a high temperature. It is formed by sintering after heating. The state of the sintering treatment is a very important factor for the life of the melting furnace 10, and accordingly the sintering method is also carried out in various ways depending on the type of the refractory.

The furnace 10 having such a structure performs periodic renovation work due to the wear and erosion of the refractory 13 according to the increase in the number of uses, in which case the refractory 13 inside the furnace 10 as a preliminary work for maintenance. Dismantling is in progress, and after dismantling, new refractories are replaced.

The refractory 13 is attached to the inner surface of the coil cement 12, the dismantling operation of the refractory 13 proceeds in a manner that a person directly removes the refractory 13 from the melting furnace 10. The cylindrical refractory body 13 having one side open is divided into four sections in the height (ie, length) direction of the melting furnace, and then removed. The refractory member 13 may be crushed or intentionally crushed. Such dismantling of the refractory 13 is not easy, there is a problem that takes a lot of people and time, there is a problem that a large amount of dust is generated in such a dismantling process is very deteriorated in the workplace environment.

Therefore, the present invention is to solve this problem, by providing a separation element between the coil cement and the refractory of the melting furnace to prevent mutual attachment of the coil cement and the refractory, to easily dismantle the refractory and thereby suppress the dust generation of the workplace The purpose is to provide a melting furnace that is easy to disassemble refractory.

In order to achieve this object, the melting furnace according to an aspect of the present invention is a tubular melting furnace shell having an open top, a coil cement attached to an inner surface of the melting furnace shell, a refractory provided inside the coil cement, and And a separating element provided between the coil cement and the refractory to prevent adhesion therebetween.

It is preferable that the bottom of the furnace shell is further provided with a through hole, the gate opening and closing the through hole, and further comprising a plate provided on the inner bottom surface of the furnace shell to close the through hole.

The melting furnace iron shell preferably includes a truncated cone inverted up and down.

Preferably, the separating element comprises rock wool.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

FIG. 2 is a schematic cross-sectional view of an internal structure of a crucible induction melting furnace according to an embodiment of the present invention, and FIG. 3 is a conceptual diagram illustrating a refractory dismantling process for the melting furnace of FIG. 2.

The outer shell of the melting furnace 100 is provided with a molten iron shell 110 to maintain the overall structure of the melting furnace 100, the inner side is provided with the coil cement 120, the separating element 140 and the refractory 130 in sequence. do. Melting furnace iron shell 110 has a function of maintaining the entire skeleton of the melting furnace 100 in a hollow cylindrical shape with an open top, the inner surface of the heating coil to perform the function of heating the solid material in the melting furnace 100 to Coil cement 120 is attached. In addition, a through hole is formed at the bottom of the melting furnace iron shell 110 and a gate 160 is provided to close the through hole. On the inner bottom surface of the melting furnace shell 110 is a plate 150 that closes the through hole and defines the bottom of the melting furnace is seated.

The coil cement 120 is formed by applying heat-resistant cement in a state in which a heating coil (not shown) is inserted therein, and a solid inside the melting furnace 100 that is a conductor by an electromagnetic induction action as an alternating current is supplied to the heating coil. Induction currents are generated in the material and the inside of the furnace is heated.

Refractory 130 is provided on the inner side of the coil cement 120, the refractory 130 is not directly attached to the inner surface of the coil cement 120, the separation element 140 between the coil cement 120 and the refractory 130 ) Is attached to the refractory 130 is attached. At this time, since the separation element 140 attached to the inner surface of the coil cement 120 is attached only to the remaining portion except for the plate 150 which is the inner bottom surface of the furnace shell 110, the refractory 130 is the separation element. It is applied to the inner side of the 140 and the inner side of the plate 150 and then sintered.

The separating element 140 has a low adhesion force with the coil cement 120 and prevents the refractory from penetrating and reaching the surface of the coil cement. The separating element 140 is a material having excellent fire resistance and is resistant to the refractory 130 when the refractory 130 is removed. Together, it should be easily removable from the coil cement 120. As the separating element 140, it is preferable to use rock wool having excellent fire resistance, but other materials may be used if the fire resistance is excellent and the adhesion to the coil cement 120 is small.

In the embodiment shown in FIG. 2, the separating element 140 is not attached to the plate 150, which is an inner bottom surface of the melting furnace shell 110, but is not limited thereto. The inner surface and the plate of the coil cement 120 ( 150) can be attached to both.

The refractory 130 has a function of protecting the coil cement 120 which is substantially heated, and has a high refractory material that does not generate heat deformation even in a high temperature state in which a solid material is heated and dissolved. The dry refractory of sinter is hardly formed by sintering.

As described in the prior art, the refractory 130 is an element that needs to be replaced periodically according to the use of the melting furnace 100, and the dismantling operation of the refractory 130 is easy according to the structure of the melting furnace 100 according to the present invention. Become.

That is, in order to remove the refractory 130 from the melting furnace 100 having such a structure, the gate 160 closing the through hole formed in the bottom of the melting furnace shell 110 is first removed. Then, as shown in Figure 3 by using the hydraulic cylinder 170 in the lower portion of the melting furnace 100 by pushing the plate 150 attached to the inner bottom surface of the melting furnace shell 110 through the through hole as a whole refractory. 130 is removed from the coil cement 120.

At this time, since the coil cement 120 and the refractory 130 are not attached by the separating element 140 but are detachably coupled to each other, the bottom of the refractory 130 is opened through the plate 150 with the hydraulic cylinder 170. When pushed upwards, the refractory 130 may be removed without being broken down as a whole.

Further, when removing the entire refractory 130 by pushing the bottom of the refractory 130 in this way, the shape of the melting furnace 100 is so that the refractory 130 can easily escape to the top of the melting furnace 100 It is preferable that the diameter is larger than the lower portion and the side wall is inclined, that is, the truncated cone is formed in the shape of the upper and lower sides of the upper and lower sides.

Looking at the characteristics of the furnace structure related to the dismantling operation in detail, the refractory 130 and the coil cement 120 is not directly attached to each other, the separation element 140 is provided therebetween. At this time, the adhesion between the separation element 140 and the coil cement 120 is smaller than the adhesion between the refractory 130 and the coil cement 120 when the separation element 140 is not provided. That is, the separating element 140 performs a function of separating each other to facilitate removal of the refractory 130 from the coil cement 120.

As shown in FIGS. 2 and 3, the melting furnace 100 having the separating element 140 between the coil cement 120 and the refractory 130 has a through hole formed at the bottom of the melting furnace during the dismantling operation of the refractory 130. The refractory 130 is separated from the melting furnace 100 by pushing the bottom of the refractory 130 upward through the hole. Alternatively, a fastener such as an appropriate ring may be fastened to the refractory 130 without forming a through hole formed at the bottom of the melting furnace 100, and then may be removed by pulling it out of the melting furnace 100.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

As described above, according to the present invention, by providing a separation element between the coil cement and the refractory of the melting furnace to prevent mutual attachment of the coil cement and the refractory, the refractory of the melting furnace can be easily dismantled. In addition, there is an effect of preventing dust generation in the workplace by separating the refractory as it is in the melting furnace without crushing.

Claims (4)

Steel shell of the furnace with an open top, A coil cement attached to the inner surface of the furnace shell; Refractories provided inside the coil cement, A separation element provided between the coil cement and the refractory to prevent adhesion therebetween, The separation element is easy melting dissolution furnace, characterized in that it comprises a rock wool. The method of claim 1, wherein the bottom of the melting furnace iron shell is formed with a through hole, the gate for opening and closing the through hole, and further comprising a plate provided on the inner bottom surface of the melting furnace iron shell to close the through hole. Refractory which is easy to dismantle. The melting furnace according to claim 1 or 2, wherein the melting furnace iron shell includes a truncated cone inverted up and down. delete

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