The present invention relates to channel inductors of channel induction furnaces.
In particular, the present invention relates to channel liners of channel inductors.
The present invention also relates to channel inductor furnaces.
Channel induction furnaces are used in industries for melting a metal (which term includes metal alloys) and maintaining the metal in a molten state. For example, channel induction furnaces are used in galvanising and foundry industries for melting Zn-containing alloys and Al-containing alloys, including Al/Zn-containing alloys, and maintaining the alloys in a molten state.
A known channel induction furnace comprises (a) a steel shell, (b) a lining of a refractory material, such as an aluminosilicate, internally of the shell, (c) a pot for containing a bath of molten metal that is defined by the refractory-lined shell, and (d) one or more than one channel inductor for heating metal that is connected to the shell and in fluid communication with the pot via a throat that extends through the refractory-lined shell to an inlet in the channel inductor.
The channel inductor comprises (i) a steel shell, (ii) a lining of a refractory material, such as an aluminosilicate, (iii) a channel defined by the refractory-lined shell that forms a path for molten metal to flow from the pot through the channel and back into the pot, and (iv) an electromagnetic coil which generates an electromagnetic field. At any given time during the operation of a channel induction furnace, molten metal in the channel of the channel inductor becomes a secondary circuit of a transformer and is heated and kept molten by currents induced by the electromagnetic field. The channel inductor is a bolt-on assembly on the shell of a channel induction furnace. The refractory material that so forms the lining is selected to accommodate a range of specific mechanical requirements, thermal insulation requirements, and resistance to chemical attack by molten metal. These requirements are competing requirements to a certain extent in the sense of needing different material properties and hence the selection of the refractory material tends to be a compromise.
Channel inductors have a limited life when exposed to molten metals such as Zn-containing and Al-containing alloys and typically fail in the following modes:
Typically, the life of channel inductors in Al-containing alloys is 6-24 months and is one of the main reasons for metal coating line shut-downs.
The applicant is developing a new inductor having greater reliability and, more particularly, less tendency so to fail due to cracking.
The new inductor is described in International publication WO2011/120079 in the name of the applicant.
The channel inductor that is described and claimed in the International publication comprises (a) a channel liner that is formed from a refractory material that is resistant to chemical attack by the molten metal in the channel and is the only material of the channel inductor that is in direct contact with the molten metal and (b) a back-up liner that supports the channel liner and is formed from a refractory material that is optimal for thermal insulation material properties and mechanical strength properties, such that the integrity of the channel liner and is not compromised during heat-up, dry-out, or operation of the channel induction furnace.
A channel inductor made with a channel liner and a back-up liner in accordance with the invention of the International publication was found to have issues with cracking when used on a manufacturing plant of the applicant for coating steel strip with Zincalume® molten metal.
The applicant has investigated the causes of the cracks and the present invention was made in the investigation.
The above discussion is not intended to be a statement of the common general knowledge in Australia and elsewhere.
The applicant carried out a post mortem on the channel inductor made in accordance with the invention of the International publication that was used on the manufacturing plant of the applicant and made the following findings, which are the basis of the present invention.
In broad terms, the present invention provides a channel inductor of a channel induction furnace, the channel inductor comprising (a) a channel liner and (b) a back-up liner that supports the channel liner such that the integrity of the channel liner is not compromised during heat-up, dry-out, or operation of the channel induction furnace.
In the context of item 1 above, the material of the channel liner may be selected so that there is a chemical reaction between the material and the molten metal in the furnace that results in the channel liner becoming more resistant to further penetration by molten metal and resistant to the development of blockages due to corundum growth within the channel. The material may be otherwise as described in item 1.
In the context of item 2 above, the material of the back-up liner may be selected to be capable of absorbing stresses due to expansion and movement of the channel liner. The material may be otherwise as described in item 2.
The channel liner may be any suitable shape.
The channel liner may be an elongate unit with the channel being in the shape of a single U (“single loop inductor”). More particularly, the channel may comprise two arms extending from a base of the channel, with a molten metal inlet in an end of one arm of the channel and a molten metal outlet in an end of the other arm of the channel, whereby molten metal can flow through one arm to the base and through the base to the other arm and along the other arm.
The channel liner may be an elongate unit with the channel being in the shape of a double U. More particularly, the channel may comprise three arms extending from a base of the channel that interconnects the arms, with a molten metal inlet in an end of a central arm of the channel and molten metal outlets in the ends of the outer arms of the channel, whereby molten metal can flow through the inner arm to the base and outwardly through the base to the outer arms and along the outer arms.
The channel liner may have a top wall, with the inlet and the outlet(s) formed in the top wall, and with the mounting flange extending outwardly from the top wall.
The channel liner may comprise a side wall that extends from a perimeter of the top wall, with the mounting flange extending outwardly from an upper edge of the side wall. This arrangement defines a vestibule or a forebay.
The present invention also provides a channel inductor furnace that comprises:
The molten metal may be selected from the group comprising Zn-containing alloys and Al-containing alloys, including Al/Zn-containing alloys. These alloys are not confined to Al and Zn and may include other elements such as Ca.
The present invention is described further by way of example with reference to the accompanying drawings, of which:
The channel inductor furnace 3 shown in
The drawing of the channel inductor 33 in
The channel inductor 33 comprises:
The channel liner 5 is a single piece elongate unit that defines the above-mentioned openings 1 and a double “U” shaped channel for molten Al/Zn alloy to flow through the channel inductor. The channel comprises a base and three parallel arms 9 extending from the base. The upper end of the central arm of the channel is an inlet 15 for molten Al/Zn alloy and the upper ends of the outer arms of the channel are outlets 17 for molten Al/Zn alloy. The base of the channel is defined by a base section 7 of the channel liner 5 and the arms of the channel are defined by upstanding sections 9 of the channel liner 5. These sections 7, 9 are thin-walled, hollow sections. The channel liner 5 has a top wall 11, and the inlet 15 and the outlets 17 for molten Al/Zn alloy flow are formed in the top wall 11. The channel liner 5 also comprises a side wall 21 that extends around the perimeter of the top wall 11 and a flange 19 that extends outwardly from the side wall 21. The top wall 11 and the side wall 21 define a vestibule or forebay. The flange 19 is provided to mount the channel liner 5 to a refractory material lining (not shown) that defines a pot throat (not shown) of a pot (not shown) of the channel inductor furnace, whereby direct contact between molten Al/Zn alloy and the channel inductor is limited to contact with the channel liner 5 only.
The channel liner support assembly comprises (a) an outer steel shell 23 and (b) a back-up lining 25. The back-up lining 25 is not shown specifically in
The present invention relates to the materials selection for the materials from which the channel liner 5 and the back-up lining 25 are made.
As indicated above, a channel inductor made in accordance with the above-mentioned International publication of the applicant was found to have issues with cracking when used on a manufacturing plant of the applicant.
The applicant carried out a post-mortem on the inductor and key points that emerged from the post mortem include the following points:
The applicant made the following findings.
One observation in the post-mortem that was not expected from an initial laboratory assessment of the channel liner material prior to using the channel inductor in the manufacturing plant was the level of apparent reaction and densification of the channel liner material.
In laboratory testing of the channel liner material, minimal reaction was observed. In the case of the channel inductor used on the manufacturing plant, the majority of the channel liner 5 was penetrated by Zincalume® molten metal used on the plant to give a darker denser looking appearance. In the few locations where there was no penetration, the appearance of a cut face showed a porous texture suffering from grain pluck-out during sectioning as if the bond strength had been reduced.
The post-mortem indicated that there had been a reduction in the SiO2 content of the channel liner material and an increase in sodium and zinc phases in the channel liner material. This indicates that there was a migration of Na and Zn vapour through the channel liner 5, ahead of the penetration of the Zincalume® molten metal, and these sodium and zinc phases lead to a reduction of silicate binding phase in the channel liner 5 which then aided further penetration.
The chemical analysis results for the penetrated, i.e. dense, zone of the channel liner 5 indicate a marked increase in Al2O3, ZnO, SiO2 and Na2O. The component that was significantly reduced was the SiC level. These changes in the dense phase are also reinforced by the XRD comparison. The XRD is semi-quantitative and must not be considered as an accurate number but it is a good indication of the species that are present in the penetrated liner and their comparative levels.
Some of the penetration phase was still in a metallic form with a combination of aluminium and aluminium silicon alloy. This was also evident in a microscopic examination. The presence of an Al/Sin alloy suggests there had been a chemical reaction between the refractory silicate phases of the channel liner 5 or reduction of the fine SiC in the matrix of the channel liner 5 to provide a source of silicon.
Both the XRD and chemical analysis indicate a reduction in the percentage of SiC in the dense phase. This may be due to an attack on the SiC or a dilution effect from the penetration into the refractory or a combination of both. There was some evidence that the dilution effect is a factor. This evidence includes a microscopic examination where the majority of larger SiC grains appeared to be unaltered and the presence of aluminium metal in the porosity of the refractory was an additional mass that would dilute the percentage of the original components. However, there was also some indication of a reaction occurring with some glassy phase surrounding some SiC grains on the outer surfaces. Also, minor components of the channel liner material such as Ba, Ti and Ca did not show a dilution effect in the altered channel liner and this supports a view that there was some reduction in the level of SiC through reaction.
In general, even though the channel liner 5 was penetrated by Zincalume® molten metal it become a denser SiC/Al2O3 containing composite with the reaction products and penetration metal making this composite even more compatible with the contact metal. One further encouraging observation was the lack of corundum growth or any other blockages in the channels and this suggests there is potential for this channel liner 5 to provide less problems with inductor blockages.
The applicant carried out test work on Dri-Vibe® composite materials to evaluate the suitability of the materials. The test work is described below.
The applicant tested three Dri-Vibe composite materials by exposing sample cups made from the materials to molten Zincalume® Al/Zn-containing alloy.
The three sample composite materials were supplied by Allied Minerals; Product A, Product B and Product C.
Product A and Product B materials are both mullite-based, metal fibre containing composite materials. Product C material is a fused alumina-based, metal fibre-containing composite material.
On the basis of the tests, the Product B is not suitable for use as a back-up liner material in a channel inductor as it was heavily penetrated by Zincalume® metal.
Product C showed no reaction and would be suitable as a back-up liner 25 from a penetration resistance perspective. The higher alumina level in this material would give the material a higher thermal conductivity and so higher heat transfer to the coil area. This material also has a tighter texture and greater strength as it was supplied.
Product A performed well in the contact tests with both the Zincalume® metal It was also more friable in nature at the end of the test and is therefore likely to resist cracking from thermal stress and absorb stresses due to the expansion and movement of the channel liner 5. Because the material is mullite-based rather than alumina-based, it has a lower thermal conductivity than the Product C material and so will help to reduce the transfer of heat to the coil zones of channel inductors.
Many modifications may be made to the embodiment of the present invention described above without departing from the spirit and scope of the invention.
By way of example, the present invention is not confined to the particular shape of the channel inductor 3 shown in the drawing.
By way of further example, the present invention is not confined to a double “U” channel liner 5 and, by way of example, also extends to single “U” channel liners 5.
By way of further example, the present invention is not confined to a channel liner 5 that is formed as a single piece unit.
By way of a further example, present invention may be used as is or modified slightly for alloys that may contain other key elements such as magnesium
Number | Date | Country | Kind |
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2013900796 | Mar 2013 | AU | national |
Filing Document | Filing Date | Country | Kind |
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PCT/AU2014/000217 | 3/6/2014 | WO | 00 |