DE19526967A1 - Method and device for inductively heating a refractory molded part - Google Patents

Abstract

Inductive pre-heating process for a channel-like refractory body of substantially rectangular internal cross-section, uses an internal inductor (4) inserted in the interior (2) of the body and removed after heating the body. Apparatus is also claimed.

Description

The invention relates to a method for inductively heating a refractory Molding that has a channel-shaped interior. Furthermore, the Invention an apparatus for performing the method.

Such molded parts are in particular part of a melt outlet device or Melt feeder in a metallurgical vessel. you will be preheated to prevent undesired cooling of the melt flowing through, especially to avoid their freezing.

DE 38 42 690 A1 describes a refractory spout for a continuous caster shown. The spout is surrounded on the outside by an induction coil with which the inner outer wall can be heated inductively. The coil is a component of the pouring component. This makes it complex and expensive, which in particular is important because such refractory pouring parts are wearing parts.  

Fireproof pouring moldings are usually heated by means of gas burners. This has the disadvantage that it burns out the carbon can come, the material component of the molded part. It is unfavorable moreover, that when it heats up to an uneven temperature distribution comes in the molding. For example, there were temperature differences of approx 400 K observed. In addition, heating up takes a considerable amount of time Claim.

The object of the invention is to quickly and evenly heat the to enable fireproof molding.

According to the invention the above object is in a method of the aforementioned Art solved in that in the interior of the refractory molding Inner inductor is introduced that the molded part by means of the inner inductor is heated and then the inner inductor from the interior is taken out.

The refractory molded part heats up quickly and evenly, for example a feed and dosing system for a belt or twin roll Caster with which the melt discharge can be interrupted and / or controlled or is adjustable.

The invention achieves increased plant availability because Freezing problems can be avoided. The method and the device are suitable not only to heat up when pouring, but also to heat up Pouring interruptions to keep the molded part at an appropriate temperature hold.  

A device for performing the method is characterized in that the inner inductor is formed from one or more cooled induction coils.

Advantageous refinements of the invention result from the subclaims and the following description of an embodiment.

The figure shows a fireproof molded part as a feed channel for a twin-roll caster with an inserted internal inductor.

A feed channel, which is known in its form, is a refractory molded part ( 1 ) made of a ceramic, carbon-containing material, which can be inductively coupled to an alternating electrical field, which results in heating. The feed channel has a channel-shaped interior ( 2 ) with a rectangular cross section. The supply duct is provided in an outer partial area with a metallic outer jacket ( 3 ), as is often used when using so-called ETA changers. The metallic outer jacket ( 3 ) therefore shields electromagnetic fields from the supply channel, so that the supply channel could not be heated uniformly with an external induction coil.

In the state shown in the figure, an inner inductor ( 4 ) is inserted into the interior ( 2 ) with a rectangular cross section. The dimensions of the inner inductor ( 4 ), in particular its length, are adapted to the interior ( 2 ) such that it extends as far as possible over the entire length of the interior ( 2 ). In addition, its outer geometry is adapted to the dimensions of the interior ( 2 ).

The internal inductor ( 4 ) has a number of cooled induction coils ( 5 ) which are connected to a generator ( 6 ). The interior ( 2 ) is elastically and / or thermally insulated from the inner inductor ( 4 ) with a layer ( 12 ), for example a ceramic glaze, so that the refractory molded part ( 1 ) does not come into contact with parts carrying electrical voltage and / or no zonal overheating occurs.

In a further embodiment of the invention, the outer surface of the inner inductor ( 4 ) is electrically and / or thermally insulated from the surfaces of the inner space ( 2 ) by means of an insulation molding ( 7 ).

It is also advantageous to adapt the inner inductor ( 4 ) to different geometries or wall thicknesses such that there are different distances between the inner inductor ( 4 ) and the surfaces of the areas to be heated. With this measure, different energy densities are generated in the molded part ( 1 ), which improves the uniformity of the heating with different wall thicknesses. The molded insulation part ( 7 ) is to be designed accordingly.

The molded insulation part ( 7 ) also serves to center the inner inductor ( 4 ) in the interior ( 2 ). The molded insulation part ( 7 ) is slid onto the induction coil ( 5 ) so that it can be replaced if necessary. The outer geometry of the molded insulation part ( 7 ) is adapted to the interior ( 2 ) in such a way that it can be easily inserted into the interior ( 2 ) and pulled out of the interior ( 2 ) with the interior inductor ( 4 ). However, the configuration may also be such that first the insulation article (7) to be inserted into the interior (2) and then the interior inductor (4) into the insulation article (7).

The molded insulation part ( 7 ) has a flange ( 8 ) at the top to limit insertion. It's open below. In other applications, e.g. B. in supply channels with lateral outflow openings, the molded insulation part ( 7 ) can be closed by means of a bottom.

In order to heat up the supply channel also in its enlarged head area ( 9 ), the inner inductor ( 4 ) is provided with an additional turn ( 10 ) above the flange ( 8 ).

The molded insulation part ( 7 ) consists of a highly heat-resistant, ceramic fiber material or ceramic foam material.

It is not necessary for the molded insulation part ( 7 ) to extend over the entire length of the internal inductor ( 4 ). Two or more molded insulation parts can also be provided distributed.

The molded insulation part ( 7 ) or the molded insulation parts need not be able to be pulled out of the interior ( 2 ). It is also possible to design the molded insulation part ( 7 ) or the molded insulation parts as the lining of the interior ( 2 ).

In order to avoid that the supply duct radiates heat to the outside, ie loses heat, it can be provided with external insulation ( 11 ), preferably made of ceramic fiber material or ceramic foam material. This improves the rapid and even heating of the feed channel.

If the supply duct is to be heated, then the internal inductor ( 4 ) with the molded insulation part ( 7 ) is inserted into the interior ( 2 ) and the generator ( 6 ) is switched on. As a result, the feed channel is inductively heated rapidly and uniformly over its entire cross section. After reaching the target temperature, the internal inductor ( 4 ) is pulled out of the supply duct. This is then pre-heated and ready for the casting operation. The inner inductor ( 4 ) can be used for many heating processes on many supply channels. Its use is therefore independent of the wear of the feed channel. The insulation molded part ( 7 ), if it is worn, can be pulled off the inner inductor ( 4 ) and replaced by a new insulation molded part. In the case of different cross sections of supply channels, molded insulation parts ( 7 ) with correspondingly different dimensions can be kept ready. This makes it possible to insert the inner inductor ( 4 ) in a centered manner even with different interior geometries.

Claims (16)

1. A method for inductively heating a refractory molded part which has a channel-shaped interior with a substantially rectangular cross-section, characterized in that an internal inductor ( 4 ) is introduced into the interior ( 2 ) that by means of the internal inductor ( 4 ) the molded part ( 1 ) is heated and then the inner inductor ( 4 ) is removed from the interior ( 2 ). 2. The method according to claim 1, characterized in that the molded part ( 1 ) is a refractory feed channel for liquid metal, in particular steel, in or on a metal melt sump. 3. The method according to claim 2, characterized in that the molded part ( 1 ) has at least in a partial area a metallic outer jacket ( 3 ). 4. Device for performing the method according to one of claims 1 to 3, characterized in that the internal inductor ( 4 ) is formed from one or more cooled induction coils ( 5 ). 5. The device according to claim 4, characterized in that the dimensions of the inner inductor ( 4 ) are adapted to the dimensions of the interior ( 2 ) of the refractory molded part ( 1 ). 6. Apparatus according to claim 4 or 5, characterized in that an electrically and / or thermally insulating layer ( 12 ) is provided between the inner inductor ( 4 ) and the interior ( 2 ). 7. Device according to one of claims 4 to 6, characterized in that the distance of the internal inductor ( 4 ) from the surfaces of the areas of the refractory molded part ( 1 ) to be heated is set so that different amounts of energy can be transmitted. 8. Device according to one of claims 4 to 7, characterized in that the internal inductor ( 4 ) in the interior ( 2 ) of the molded part ( 1 ) is centered. 9. Device according to one of claims 7 or 8, characterized in that the centering I distances is / are predetermined by an insulating molded part ( 7 ) made of an electrically and / or thermally insulating material. 10. Device according to one of claims 7 to 9, characterized in that the insulating molded part ( 7 ) is made of highly heat-resistant, ceramic fiber material or ceramic foam material. 11. Device according to one of claims 8 to 10, characterized in that the molded insulating part ( 7 ) on the inner inductor ( 4 ) can be pushed. 12. Device according to one of claims 8 to 11, characterized in that the molded insulating part ( 7 ) on the inner inductor ( 4 ) is replaceable. 13. Device according to one of claims 4 to 12, characterized in that the molded insulating part ( 7 ) and the refractory molded part ( 1 ) or the internal inductor ( 4 ) are easily detachable from each other after heating. 14. Device according to one of claims 8 to 12, characterized in that the insulating molded part ( 7 ) in the interior ( 2 ) of the molded part ( 1 ) is arranged at least as its partial lining. 15. The apparatus according to claim 14, characterized, that the insulation molding disintegrates after heating. 16. Device according to one of claims 3 to 15, characterized in that the molded part ( 1 ) has an outer insulation ( 11 ), preferably made of ceramic fiber material or ceramic foam material.