I. Field of the Invention
This invention relates to vessels used for containing and/or conveying molten metals and, especially, to such vessels having two or more refractory lining units that come into direct contact with each other and with the molten metals during use. More particularly, the invention addresses issues of molten metal leakage and thermal optimization in such vessels.
II. Background Art
A variety of vessels for containing and/or conveying molten metals are known. For example, molten metals such as molten aluminum, copper, steel, etc., are frequently conveyed through elongated troughs (sometimes called launders, runners, etc.) from one location to another, e.g. from a metal melting furnace to a casting mold or casting apparatus. In recent times, it has become usual to make such troughs out of modular trough sections that can be used alone or joined together to provide an integral trough of any desirable length. Each trough section usually includes a refractory liner that in use comes into contact with and conveys the molten metal from one end of the trough to the other. The liner may be surrounded by a heat insulating material, and the combined structure may be held within an external housing or shell made of metal or other rigid material. The ends of each trough section may be provided with an enlarged cross-plate or flange that provides structural support and facilitates the connection of one trough section to another (e.g. by bolting abutting flanges together).
It is also known to provide metal conveying troughs with heating means to maintain the temperature of molten metal as it is conveyed through the trough, and such heating means may be positioned within the housing close to an external surface of the refractory liner so that heat is transferred through the liner wall to the metal within. For example, U.S. Pat. No. 6,973,955 which issued on Dec. 13, 2005 to Tingey et al. discloses a trough section having an electrical heating element beneath the refractory liner held within an external metal housing. In this case, the refractory liner is made of a material of relatively high heat conductivity, e.g. silicon carbide or graphite. A disadvantage noted for this arrangement is that molten metal may leak from the liner (e.g. through cracks that may develop during use) and cause damage to the heating element. To protect against this, a metal intrusion barrier is provided between the bottom of the refractory liner and the heating element. The barrier may take the form of a screen or mesh made of a non-wettable (to molten metal) heat-resistant metal alloy, e.g. an alloy of Fe—Ni—Cr. While the molten metal intrusion barrier of the above patent can be effective, it is usually difficult to install in such a way that all of the molten metal resulting from a leak is prevented from contacting the heating element. Also, this solution to the problem of metal leakage tends to be expensive, particularly when exotic alloys are employed for the barrier.
The problem of molten metal leakage from the refractory liner is increased when the liner itself is made up of two or more liner units abutted together within a trough or trough section. The joint between the two liner units forms a weak spot where metal may penetrate the liner. The use of two or more such units is necessary in many cases because there is a practical limit to the lengths in which the refractory liner units can be made without increasing the risk of cracking or mechanical failure, but trough sections longer than this limit may be necessary to minimize the number of sections required for a complete trough run. When a trough section contains two or more refractory liner units joined end to end, the units are generally held together with compressive force (provided by the housing and end flanges) and the intervening joint is commonly sealed only with a compressible layer of refractory paper or refractory rope. Over time, such seals degrade and an amount of molten metal commonly leaks through the liner into the interior of the housing. If the trough section contains one or more heating elements or other devices, the molten metal will often find its way to such heating elements or devices and cause equipment damage and electrical shorts.
A further disadvantage of known equipment is that, when heated troughs or trough sections are utilized, a refractory lining of high heat conductivity is generally utilized to allow efficient heat transfer through the refractory material of the trough liner. However, this can have the disadvantage that heat is conducted along the refractory liner to the metal end flange, thereby creating a region of high heat loss from the liner and a hazardous region of high temperature on the exterior of the housing.
Accordingly, there is a need for improvement of trough sections of this general kind in order to address some or all of these problems and possibly additional issues.
An exemplary embodiment provides a vessel used for containing molten metal. The vessel includes a refractory liner having at least two refractory liner units positioned end to end, with a joint between the units, the units each having an exterior surface and a metal-contacting interior surface. The vessel also has a housing at least partially surrounding the exterior surfaces of the refractory liner units with a gap present between the exterior surfaces and the housing. Molten metal confinement elements, impenetrable by molten metal, are positioned on opposite sides of the joint within the gap, at least below a horizontal level corresponding to a predetermined maximum working height of molten metal held within the vessel in use, to partition the gap into a molten metal confinement region between the elements and at least one other region. The confinement elements prevent molten metal in the confinement region from penetrating into the other region(s) of the gap within the housing so that these regions may be used to house equipment (e.g. heating devices such as electrical heaters) that would be damaged by contact with molten metal. Thus, rather than providing a barrier to restrain molten metal that may penetrate through any part of the refractory liner of the vessel, a confinement area or escape route is provided for any such penetrating molten metal based on the observation that the most likely place for such metal penetration is at junctions between units that make up the refractory liner. In this way, the molten metal is kept away from areas of the vessel interior that where damage may be caused.
Another exemplary embodiment relates to a vessel used for containing molten metal having an inlet for molten metal and an outlet for molten metal. The vessel includes a refractory liner made up of abutting refractory liner units. The units include at least one intermediate refractory liner unit and two end units with one of the end units being positioned at the molten metal inlet and the other of the end units positioned at the molten metal outlet. The intermediate unit(s) is (are) positioned between the end units remote from the inlet and the outlet. The refractory liner units each have an exterior surface and a metal-contacting interior surface. A housing contacts the end units and at least partially surrounds the exterior surfaces of the refractory liner units with a gap present between the exterior surfaces of the intermediate unit(s) and the housing. A heating device is positioned in the gap adjacent to the intermediate unit(s). The liner units are made of refractory materials and the material the end units (or at least one of them) has a lower heat conductivity than the refractory material of the intermediate unit(s). This maximizes heat penetration from the heating device through the refractory material of the intermediate unit(s), but minimizes heat loss through the end unit(s) to the housing adjacent to the molten metal inlet and outlet.
The both exemplary embodiments, the vessel may take a variety of forms, but is preferably a trough or trough section used for conveying molten metal, in which case the refractory liner is elongated and has an inlet for molten metal inflow at one end and an outlet for molten metal outflow at an opposite end. The metal contacting interior surfaces of the liner units may form an open-topped molten metal conveying channel or, alternatively, a closed channel (e.g. with the refractory liner forming a pipe).
A preferred exemplary embodiment relates to a trough section for conveying molten metal, the trough section comprising: at least two refractory lining units positioned end to end, with a joint between the units, to form an elongated refractory lining, the units each having an exterior surface and a longitudinal metal-conveying channel open at an upper side of the exterior surface, a housing at least partially surrounding the refractory lining units, except at the upper sides, with a gap formed between the refractory lining units and the housing; and a pair of metal-confinement elements, impervious to molten metal, positioned one on each side of the joint and surrounding the exterior surfaces of the refractory lining units, at least below a horizontal level corresponding to a predetermined maximum working height of molten metal conveyed by the trough section in use, and bridging the gap between the exterior surface and an internal surface of the housing; wherein each of the confinement elements has surfaces conforming in shape to the external surface and to the internal surface to thereby form a molten-metal confinement region between the confinement elements for containing and confining any molten metal that in use leaks from the joint.
Another preferred exemplary embodiment provides a trough section for conveying molten metal, the trough section comprising: at least two refractory lining units positioned end to end to form an elongated refractory lining having opposed longitudinal ends, the units each having a longitudinal metal-conveying channel open at an upper side, and a housing at least partially surrounding the refractory lining units, except at the upper sides, and including a transverse end wall contacting and partially surrounding one of the longitudinal ends of the refractory lining, wherein the refractory lining unit contacting the transverse end wall is made of a refractory material of lower heat conductivity than a material of at least one other refractory lining unit forming the elongated refractory lining.
It is preferable to provide trough sections according to the exemplary embodiments with at least two intermediate units per trough section because refractory lining units have a greater tendency to crack as their length increases, so there is a practical maximum length in which they can be made (which may vary according to the material chosen but is often in the range of 400 to 1100 mm). Furthermore, when the refractory lining of a trough section is heated from within the trough section, it is desirable to make the section as long as possible to maximize the length of trough that is heated. The end regions of trough sections where the sections are joined cannot be heated and, indeed, heat loss to the section end walls may occur there, so it is desirable to minimize the number of trough sections used to produce a required length of trough. This maximizes the heat input per unit trough length. While it is not preferred, a short trough module constructed with a single intermediate refractory lining unit may be necessary due to the constraints of distance between other equipment in the molten metal stream. Trough sections can generally be made in any suitable length by adjusting the number of refractory lining units per trough. Lengths from 570 mm up to 2 m, more preferably 1300 to 1800 mm, are usual. The actual length chosen from this range is determined by ease of installation, minimizing unheated sections required to interface with other equipment in the molten metal stream, and ease of handling and transportation.
The trough sections of the exemplary embodiments may be used to convey molten metals of any kind provide the refractory lining units (and metal confinement elements) are made of materials that can withstand the temperatures encountered without deformation, melting, disintegration or chemical reaction. Ideally, the refractory materials withstand temperatures up to 1200° C., which would make them suitable for aluminum and copper, but not steel (refractories capable of withstanding higher temperatures would be required for steel and are available). Most preferably, the trough sections are intended for use with aluminum and its alloys, in which case the refractory materials would have to withstand working temperatures in the range of only 400 to 800° C.
The term “refractory material” as used herein to refer to metal containment vessels is intended to include all materials that are relatively resistant to attack by molten metals and that are capable of retaining their strength at the high temperatures contemplated for the vessels. Such materials include, but are not limited to, ceramic materials (inorganic non-metallic solids and heat-resistant glasses) and non-metals. A non-limiting list of suitable materials includes the following: the oxides of aluminum (alumina), silicon (silica, particularly fused silica), magnesium (magnesia), calcium (lime), zirconium (zirconia), boron (boron oxide); metal carbides, borides, nitrides, silicides, such as silicon carbide, particularly nitride-bonded silicon carbide (SiC/Si3N4), boron carbide, boron nitride; aluminosilicates, e.g. calcium aluminum silicate; composite materials (e.g. composites of oxides and non-oxides); glasses, including machinable glasses; mineral wools of fibers or mixtures thereof; carbon or graphite; and the like.
A first exemplary embodiment of the invention, illustrating a metal containment vessel in the form of a trough section of a kind used for conveying molten metal from one location to another, is shown in
The metal-conveying channel 11 is formed by four refractory liner units that together make up an elongated refractory liner 12 that contains and conveys the molten metal from one end of the trough section to the other during use. The four refractory liner units comprise two intermediate units 14 and 15, and two end units 16 and 17. These open-topped generally U-shaped units are aligned longitudinally to form the liner 12 and are held in place within the housing 20. The housing is usually made of a metal such as steel and (in addition to the top plates mentioned above) has sidewalls 21, a bottom wall 22 and a pair of enlarged transverse end walls 23 that form flanges that support the section and facilitate attachment of one such trough section to another (e.g. by bolting flanges of adjacent sections together). The housing 20 surrounds the refractory liner units except at the open upper sides thereof but with a gap 24 present between the refractory lining units and adjacent inside surfaces of the sidewalls 21 and bottom wall 22. The sidewalls, bottom wall and end walls may be joined together so that any molten metal that leaks into the housing from the channel 11 does not leak out, or alternatively, they may have gaps (e.g. between the bottom wall and the sidewalls), that allows molten metal leakage.
The two intermediate refractory liner units 14 and 15 butt together to form a joint 25 that is sealed against molten metal leakage, e.g. by providing a layer of a compressible refractory paper between the units or a refractory rope compressed within a groove 18 provided in the abutting faces or cut into the channel faces of the units to overlap the joint. Similar joints 26 and 27 are formed between the end units 16, 17 and their abutting intermediate units 14 and 15, although the end units have parts that extend for a short distance along the outside of the intermediate units as shown (see
As noted above, the two intermediate refractory liner units 14 and 15 abut each other at joint 25. A pair of metal confinement elements 35 and 36 is provided in gap 24, with one such element being located on each opposite side of the joint 25 to define a metal confinement region 38 therebetween. This region is referred to as a metal-confinement region because, if molten metal leaks from the channel 11 through the joint 25 during use of the trough section—as may occur if the seal between units 14 and 15 begins to fail—the molten metal leaks into the confinement region 38 and is constrained against movement to other parts of the interior of the housing 20. If the housing 20 has no outlets in the confinement region, any molten metal that leaks into the confinement region is held there permanently and may solidify on contact with the interior surfaces of the housing. On the other hand, if the housing 20 has outlets (e.g. if there is a gap between the bottom wall and the sidewalls of the housing), molten metal may leak out to the exterior of the housing (if it remains molten) where it may optionally be collected in a suitable container or channel. As mentioned, an important feature is that the confinement elements 35 and 36 prevent movement of molten metal beyond the confinement region to other interior parts of the housing. To ensure such confinement of the molten metal, the elements 35 and 36, which are shown in isolation in
To form the confinement region 38, the confinement elements 35 and 36 are spaced apart from each other and from the joint 25, although the spacing may be virtually zero provided there is enough space to accommodate even a small amount of the molten metal and to allow it to escape. As the spacing increases, the capacity of the confinement region for holding molten metal desirably increases, but the size of other regions of the gap within the housing, i.e. regions that may be needed for other purposes, undesirably decreases. In practice the spacing between these elements may range from 0 to 150 mm, preferably 0 to 100 mm, and more preferably from 10 to 50 mm. If the confinement region 38 is enclosed on all sides, it could conceivably fill up with molten metal if the amount of leakage is sufficiently great, but this would not matter, provided the desired effect of preventing leakage into other regions of the housing were prevented.
In the drawings, the confinement elements 35 and 36 extend up to the top of the refractory liner units on each side of the channel 11. In practice, however, there is no need to extend these elements higher than a horizontal level corresponding to a predetermined maximum working height of molten metal conveyed through the trough section in use, as there will be no molten metal leakage above this level. This level is indicated by dashed line 43 in
As noted, the confinement elements 35 and 36 prevent any molten metal leaking from joint 25 from moving to other regions of the interior of the housing 20. This is particularly desirable when these other regions contain devices that may be harmed by contact with molten metal, e.g. electrical heating elements 45 used to keep the molten metal in channel 11 at a desired elevated temperature. Such elements may be of the kind disclosed in U.S. Pat. No. 6,973,955 to Tingey et al. (the disclosure of which is specifically incorporated herein by this reference). Although the exemplary embodiment is designed to keep molten metal out of the regions containing such devices, it may also be prudent to provide one or more drain holes in these other regions at a level below the lowermost point of the devices. Hence any molten metal reaching these regions (e.g. from a crack in the refractory liner remote from joint 25) will leak out without causing harm to the devices.
While the exemplary embodiment of
Materials of high heat conductivity suitable for the intermediate refractory liner units 14, 15 include silicon carbide, alumina, cast iron, graphite, etc. The intermediate refractory liner units may if desired be coated, at least on their external surfaces, with a conductive, highly heat absorptive coating to maximize radiant heat transfer from heating elements 45. Materials suitable for the refractory liner end units 16, 17 include fused silica, alumina, alumina-silica blends, calcium silicate, etc.
The end units 16 and 17 are preferably be made as short as possible in the longitudinal direction of the channel 11 while still providing adequate structural integrity and good insulation against heat loss to the end wall 23 of the housing. In practice, suitable lengths depend on the material from which the end units are made, but are generally in a range from 25 to 200 mm, and preferably from 75 to 150 mm. It is also desirable to provide an end unit of relatively low heat conductivity at both ends of the trough section, although an end unit of this kind may be provided at just one end of the trough section when circumstances make it appropriate, e.g. if one end of the trough section connects directly to a metal melting furnace so that the end wall 23 is at such a high temperature from proximity to the furnace that heat loss through the end wall is negligible or even heat gain is conceivable. The end unit may then be made of a material of higher heat conductivity (similar to the intermediate units) to ensure thermal transfer to the molten metal in the channel even at this end of the trough section.
While
As mentioned earlier, all of the trough sections of the exemplary embodiments may be provided with one or more layers of heat insulating material in available space within the gap between the refractory liner 12 and the inner surface of the housing 20, particularly adjacent to the sidewalls. The insulation may be, for example, an alumino-silicate refractory fibrous board, microporous insulation (e.g. silica fume, titanium dioxide, silicon carbide blend), wollastonite, mineral wool, etc. The insulation keeps the outer surfaces of the housing at reasonably low temperatures so that operators are not exposed to undue risk of sustaining burns, and helps to maintain the desired elevated temperature of the molten metal within the metal channel. Clearly, such insulation is not positioned between heating elements and the refractory liner units in those embodiments that employ such heating elements, and optionally the confinement regions 38 are kept free of insulation to force the freeze plane of escaping molten metal to be at the inside surface of the housing 20.
While the above embodiments show trough sections as examples of molten metal containing vessels, other vessels having refractory liners of this kind may be employed, e.g. containers for molten metal filters, containers for molten metal degassers, crucibles, or the like. When the vessel is a trough or trough section, the trough or trough section may have an open metal-conveying channel that extends into the trough or trough section from an upper surface, e.g. as shown in the exemplified embodiments. Alternatively, the channel may be entirely enclosed, e.g. in the form of a tubular hole passing through the trough or trough section from one end to the other, in which case the refractory liner resembles a tube or pipe. In another exemplary embodiment, the vessel acts as a container in which molten metal is degassed, e.g. as in a so-called “Alcan compact metal degasser” as disclosed in PCT patent publication WO 95/21273 published on Aug. 10, 1995 (the disclosure of which is incorporated herein by reference). The degassing operation removes hydrogen and other impurities from a molten metal stream as it travels from a furnace to a casting table. Such a vessel includes an internal volume for molten metal containment into which rotatable degasser impellers project from above. The vessel may be used for batch processing, or it may be part of a metal distribution system attached to metal conveying vessels. In general, the vessel may be any refractory metal containment vessel having several abutting refractory liner units positioned within a housing.
The vessels to which the invention relates are normally intended for containing molten aluminum and aluminum alloys, but could be used for containing other molten metals, particularly those having similar melting points to aluminum, e.g. magnesium, lead, tin and zinc (which have lower melting points than aluminum) and copper and gold (that have higher melting points than aluminum).
This application is a continuation of U.S. non-provisional patent application Ser. No. 13/066,474 filed Apr. 14, 2011, now issued as U.S. Pat. No. 8,657,164, which claims the priority right of prior U.S. provisional patent application Ser. No. 61/342,841 filed Apr. 19, 2010 by applicants named herein. The entire disclosures of application Ser. No. 13/066,474 and application Ser. No. 61/342,841 are incorporated herein by this reference for all purposes.
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Number | Date | Country | |
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20140117596 A1 | May 2014 | US |
Number | Date | Country | |
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Number | Date | Country | |
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Parent | 13066474 | Apr 2011 | US |
Child | 14149903 | US |