The present invention relates to smelting furnaces with walls of refractory brick and copper coolers that line the inside walls of their steel containment shells. And more specifically, to improving the campaign lives of such furnaces by relieving a lowest base tier of refractory-brick wall of weight they conventionally bear from above in supporting the upper tiers refractory-brick wall. A modular, liquid-cooled cantilever support shelf is fixed just above the lowest base tier to the steel containment shells. The cantilever support shelf then bears all the weight of the upper tiers of refractory brick walls.
AUSMELT®/ISASMELT™ non-ferrous smelters drop moist solid feeds from above into a tall cylindrical furnace with a matte/metal/slag bath while also blowing oxygen-enriched air down in through a submerged vertical lance. (AUSMELT® of Outotec, and ISASMELT™ of Glencore Technology.) Once fully melted, the matte/slag is periodically tapped into another furnace for separation. These are often referred to as Top Submerged Lance (TSL) furnaces.
The AUSMELT top submerged lance technology optimizes feed material dissolution, energy transfer, reaction, primary combustion, and other critical processes which all take place in the slag layer inside the smelter vessel. Submerging the gas injection ensures that reactions occur rapidly and residence times will be low due to an intense agitation that is caused in the vessel. The degree of oxidation and reduction can be controlled by adjusting the fuel:oxygen ratio supplied to the lance, and the proportion of reductant coal to feed. This easy way to control the oxidation and reduction enables the furnace to be selectively operated between strongly oxidizing through strongly reducing conditions. Operating temperatures in AUSMELT top submerged lance furnaces can range from 900° C. to 1400° C.
ISASMELT furnaces are top-entry submerged-lance upright-cylindrical shaped steel vessels that are lined with refractory bricks. Inside at the bottom of the furnace, in the “liquid zone”, is a molten bath of slag, matte, or metal. A hollow steel lance is lowered into the bath through a hole in the roof of the furnace, and air or oxygen-enriched air is forcefully injected through the lance to agitate the bath.
Mineral concentrates and other materials are dropped into the bath from above through a hole in the roof. If suitably fine, such materials can also be injected down the lance with the air. An intense reaction results in a small volume when the feed materials contact, heat, and react with the oxygen in the injected gas.
Lances may include “swirlers” that force the injected gas to vortex against the walls inside to more effectively cool the lance's walls. Outside of the lance, a layer of slag will freeze on the air-cooled walls. Such frozen slag helps isolate the steel lance from the surrounding temperatures which could be high enough to melt the lance if contacted directly. But ultimately the steel tip of all submerged lances will wear out from the immediately surrounding violence and need replacement. The good news is worn lances are easily refurbished and replaced. The worn tips are simply cut off and new tips are welded onto the original lance body.
ISASMELT furnaces typically operate in the range of 1000-1200° C., depending on their application. The refractory bricks that line the inside floors and walls of the furnaces are there to protect the steel shell from the severe heat inside the furnace that would otherwise quickly melt the steel shell.
Refractory bricks are subject to corrosion, wear, uneven heating, swelling with ingrained melt, and fractures because they are brittle. But the refractory bricks in the liquid bath zone of a furnace are especially subject to corrosion and thinning. So as they corrode and thin, they are less able to support the weight of refractory brick wall lining above. (Conventional practice has been to direct the entire weight of the complete refractory brick wall lining vertically down to its ring footing.) Embodiments of the present invention divide the weight amongst one or more upper tiers each fitted with cantilevered shelves.
Smelted products are removed from furnaces through tap holes in a procedure called “tapping”. Such tapping can be continuous, or done in batches. At the end of a tap, the tap holes can be closed by blocking them with clay plugs. They can be reopened by thermic lances and/or by drilling. Alternatively, the melt can be removed from the furnace using either an underflow or an overflow weir for continuous discharge of molten material.
The smelted products thus tapped will separate on their own once they arrive and settle in a rotary holding furnace, an electric furnace, a settling vessel, a melt-transporting ladle, or granulated.
Most of the large amount of energy needed for smelting that is used to heat and melt sulfide concentrates and feed materials is a product of the reaction of oxygen with sulfur and iron in the concentrates. A small amount of supplemental energy that is needed to balance out losses is supplied by injecting coal, coke, petroleum coke, oil, or natural gas to react with the injected air. Solid fuels are best added through the top of the furnace along with the feed materials, and liquid and gas fuels can be injected with the air forced down inside the lance.
Eventually all furnaces reach the ends of their campaign lives. Such ends-of-life are preferably planned for and expected, rather than catastrophic, as can occur with a refractory-brick wall collapse.
The furnaces we are concerned with here stack refractory-brick in walls that are not fixed to the inner walls of the steel vessels. The bricks in these walls wear differently due to variances in abrasion, corrosion, and other factors that occur below the bath level and above the bath level.
Conventional furnaces of this type stacked all the refractory-brick in the walls in one uninterrupted pile. Some include floating cooling blocks in these stacks that moved with the brick under thermal expansion forces. Each row of brick and floating cooling blocks has to support the weight of every row above it and pass that weight down until the burden reaches the furnace floor.
The portion of refractory-brick walls at the bottom around the bath zone has to bear the most weight and is subject to severe wear.
Briefly, furnace embodiments of the present invention include at least one row of fixed copper coolers arranged in a cantilevered horizontal shelf inside. These are fastened to an external steel ring support through fenestrations in the steel containment shell. These shelves take all the weight of refractory brick and floating cooling blocks stacked on them and redirect the weight into the steel containment shell. Each fixed copper cooler in the shelves hangs shoulder-to-shoulder to cantilever over any refractory brick and floating cooling blocks stacked beneath. The lower portion of the wall is thus relieved of the weight of the upper wall. When relieved of such weight, the risks of sudden catastrophic failure of the lower walls are reduced. These bricks in the lower walls can also be allowed to wear and thin beyond what would be reasonable in a conventional design without any cantilevered shelving.
Shelves of fixed cantilevered copper coolers in embodiments of the present invention provide full support of the weight of walls of brick and floating cooling blocks stacked in rows and ringed around just inside the steel containment shells of furnaces. Some furnace applications will require two or more such shelves of fixed cantilevered copper coolers and brick.
Any vertical copper coolers or rings of cooling blocks lower in the furnace and situated below a shelf ring of fixed cantilever copper coolers will be independently supported from below. Any rings of copper coolers positioned below a fixed cantilever copper cooler can have brick, castable, rammix, plastic refractory, or no refractory facings. Hard facings welded on them would also be appropriate.
Our fixed cantilever copper coolers partition tall refractory linings into shorter independent stacks and thereby eliminate conventional problems with differential thermal expansion. These shelves of fixed cantilever copper coolers reduce the risks of sudden failure where only brick is placed below. Such lower brick can suffer severe local wear and may buckle and fail if it must bear the weight of brick above. So the shelves of fixed cantilever copper coolers take the weight and vertical pressure off the high wear lower brick, and reduce the possibility of sudden brick lining wall collapse.
Brick supported this way with one or more shelf rings of fixed cantilevered copper coolers, makes it practical to rebuild only the highly worn parts of the refractory. Without such intermediary support, replacing the lower brick would mean all of the brick not anchored to the shell above would have to be replaced as well every time.
Each individual cantilevered copper cooler arranged in horizontal shelf 110 is typically made of cast copper. And as such, the copper hot face must be protected from wear, abrasion, and corrosion by slag, matte or other frozen material that is assisted in adhering by grooves, pockets, or other textured patterns in the vertical face.
Furnace 100 is fully lined inside with walls of refractory brick 120 stacked dry or mortared to one another. These are set with paste, castable, powder, rammix, brick, and/or mortar up against steel containment shell 102. Some installations will include floating cooling blocks 122. And these can be faced with castable or rammed refractory to protect their hot face from wear. Areas which could be exposed to wear or oxidation may be protected with a weld overlay or other hardfacing.
Hardfacings like weld overlays applied to copper cooling blocks will increase their wear resistance, and thus increase the campaign life of the furnace. Wear results from abrasion, impacts, metal-to-metal contacts, heat, and corrosion of the hot face surface. I prefer here hardfacings that comprise at least one alloy of nickel and chromium which fused by welding. Such is applied to less than the entire surface, and only on those portions of the surface of the hot face predetermined to be more exposed during use to wear than are any other portions.
These hardfacings are applied as a weld overlay of molten metal in an inert shield gas. One useful material that will produce good results is any alloy between nickel and chromium that has a minimum of 55% nickel, a minimum of 18% chromium, and a maximum of 6% iron.
A complete loss of cooling in the individual cantilevered copper coolers arranged in horizontal shelf 110 would subject the brick walls they support above to sudden collapse if the copper gets hot enough to melt. A steel failsafe support that would catch and prevent such a collapse is illustrated in
The lower row of fenestrations allows a middle partition weight 212 of middle tier of bricks and floating cooling blocks to transfer through a fixed cantilevered shelf 214 outside to a steel external support ring 216. All this weight too is diverted 218 into the steel containment shell.
A bottom partition weight 220 of bricks and copper coolers, especially in the liquid bath area bears directly down onto a furnace floor 222. Such bricks and copper coolers are thus not burdened with the substantial weight of partitions 204 and 212 above.
This leads to a major advantage of embodiments of the present invention in that the bottom section of refractory brick lining in the bath zone can be allowed to corrode and thin beyond conventional minimums because it doesn't have to support all the weight above. Thus extending the useful campaign life and even increasing the bath volume.
The refractory brick in the lower partition contains a liquid bath of slag, matte, and/or metal. Such liquid bath is highly corrosive to refractory brick and will thin the brick over time. Such thinning will eventually compromise the ability of the refractory brick lining to support the weight of more elevated sections of refractory brick lining.
Over the campaign life of furnaces like furnaces 100 (
The thermal expansion and growth of the refractory brick linings creates challenges in keeping the areas just under each cantilever shelf of copper coolers sealed. Hot process gases must not be allowed to find and escape through cracks and fractures in the refractory. So any seals must accommodate the expansion and growth of the refractory brick linings.
Embodiments of the present therefore include at least a vertical slip joint or a compressible refractory material to seal the areas just under the cantilever shelf of copper coolers.
This second horizontal copper cooler cantilever shelf 210 need not necessarily include splash block 212. In such case, the second horizontal copper cooler cantilever shelf 210 could be identical to the first horizontal copper cooler cantilever shelf 206 as shown in
The benefit in bolting both the first and second horizontal copper cooler cantilever shelves 206 and 210 with fasteners to the cylindrical steel vessel 208 is their respective weight loads can be fully redirected into the steel vessel 208, and off the refractory brick in bath zone 204. The cylindrical steel vessel 208 is therefore conscripted to carry all such weight. The more elevated refractory brick lining and horizontal copper coolers 214 and 216 are allowed to float because they will expand vertically upwards as the refractory material swells over the campaign life.
An external, horizontal steel ring rib 220 is an important structural component of the cylindrical steel vessel 208. Such provides a strong ledge on which machine bolts can be used to secure the individual copper coolers of the first horizontal copper cooler cantilever shelf 206.
Another external, horizontal steel ring rib 222, higher above, is one more essential structural component of cylindrical steel vessel 208. This too provides a second strong ledge on which machine bolts can be used to secure the individual copper coolers of the second horizontal copper cooler cantilever shelf 210.
The individual cantilever copper coolers 306 and 308 do not float inside steel vessel 302. All the other vertical and horizontal copper coolers do need to float as the refractory brick they cool swells and expands over the campaign life of the furnace. Such ability to float is hinted at by the many large oversize holes that perforate the steel vessel 302 to accommodate numerous liquid coolant line connections visible in
Sometimes individual cantilever copper coolers 306 and 308 will need to be replaced. It would be a major advantage if such maintenance could be accomplished without also having to remove neighboring copper coolers or refractory brick to gain access.
Each cantilever copper cooler 501 and 502 has one or more mounting foot-mounting bosses 508-511 drilled for machine bolts 512-519.
A V-wedge of castable thus formed at each radial joint locks on top of the copper coolers, helps support the refractory brick above, and prevents any flow of hot smelting gases between the copper coolers.
Alternative embodiments may not include this second cantilevered cantilever shelf 600, while still others may have a third and a fourth. A steel shelf may also be installed immediately above any horizontal cantilever shelf of copper coolers to provide continuing support of the refractory brick above it should there be a loss of liquid cooling.
A method embodiment of the present invention extends the campaign life of refractory brick in vertically orientated metal smelting or converting furnaces. A vertically orientated metal smelting or converting furnace vessel is partitioned into bath zone and at least one upper zone above the bath zone. The inside of the bath zone of the vessel is lined with a first lining of refractory brick such that its weight is fully supported by a floor at the bottom. A first horizontal ringed cantilever shelf of individually and independently replaceable liquid-cooled cooling elements are fastened at a fixed elevation and are mechanically fully supported by their respective attachments on the outside of the furnace vessel above the bath zone. The inside of a first upper zone of the vessel is lined with a second lining of refractory brick such that its weight is mechanically fully supported by a protruding ledge of the first horizontal cantilever shelf.
The steel failsafe shelf support hanger 700 need only hold off a collapse of brick wall 702 long enough to allow the furnace to be shut down and a repair crew sent in to replace copper cooler shelf 110. The steel material used should be carbon steel to facilitate welding 704 a vertical wall part 705 to the steel containment shell 102. It can therefore be thin, perforated, vented, slotted, welded wire, etc.
A number of gussets 706 are included to keep a horizontal shelf part 708 stiff enough to assume the weight of brick wall 702 if copper cooler shelf 110 melts away.
Although particular embodiments of the present invention have been described and illustrated, such is not intended to limit the invention. Modifications and changes will no doubt become apparent to those skilled in the art, and it is intended that the invention only be limited by the scope of the appended claims.