Embodiments of the present invention relate to blast furnaces, the stave coolers used inside them, and the hardware used to mount these stave coolers and connect and circulate coolants. More particularly, embodiments of the present invention embed a steel footer/anchor ring in a stave copper casting that is gas-tight and mechanically locked in by exotic dissimilar metal welding, and/or by entrained liquid copper that passed through and froze inside openings preformed in the steel footer rings. A pipe collection box of carbon steel is welded on afterwards that is strong enough to support the full weight of the stave and gas-tight to contain lethal process gases associated with blast furnaces.
Purpose of water-cooled components like stave coolers in blast furnaces is to arrest erosion/corrosion of the refractory lining, e.g., to establish a stable blast furnace crucible. Water-cooled components enable stable openings for passage of process constituents into or out of the blast furnace. For example, Tuyeres.
Back as early as June 2011, Todd G. Smith and Allan J. MacRae jointly invented a “Can” on a steel backing plate they used to support cast copper stave coolers inside blast furnaces. The advantage of the Can was all the pipe circuit inlet ends and outlet ends were clustered together inside the Can for exit outside in one group per stave.
Even years earlier, in 1980, Mashinenfabrik Ausberg-Nurenberg (MAN) of Oberhausen, Germany had built a plate cooler in which a large diameter bulkhead coupler was threaded into the the cooler's backside and it too had all its pipe circuit inlet ends and outlet ends clustered together inside what they labeled a “Befestigunggstutzen” for exit outside the blast furnace in one group per stave. Both were concerned with keeping dangerous lethal process gases sealed up inside the blast furnace containment shell. The cast-into-copper “can” depended on good copper-steel bonds and steel-to-steel welds, the “Befestigunggstutzen” needed heavy duty specialized gas-sealing washers and large strong locknuts.
We discussed the challenges and techniques of gas sealing blast furnace stave coolers in a parent to this application that was published as US Published Patent Application US2013-0203007 on Aug. 8, 2013.
What is needed now is a closed Can that can be attached well enough to the backside of a cast copper stave cooler that it will not pull off after several years of service and that will continue to contain lethal process gases inside for its entire campaign life. All the while supporting the 3,000+ kg weight of a ten foot tall all-copper stave cooler inside the blast furnace shell.
Stave coolers 108 are about forty inches wide at the top and about forty three inches wide at the bottom to accommodate the cone effect of the stack 102 narrowing in diameter at the top. Stave coolers 110 are about forty three inches wide top and bottom because the top and bottom diameters of Belly 104 are about the same. Stave coolers 112 are about forty three inches wide at the top and about forty inches wide at the bottom to accommodate the inverse cone effect of the Bosh narrowing in diameter at the bottom.
A single blast furnace shell 114 typically made of two inch carbon steel plate, and provides an outermost blast furnace containment. Its walls and penetrations 115 provide the necessary support on which to hang every stave cooler 108, 110, and 112. The penetrations 115 can be cut onsite from the outside with a gas torch. If access to the inside is possible, the job of cutting penetrations 115 is much easier.
Each stave cooler can typically weigh 3,000 kg, principally consisting of very pure copper casting and associated piping and fittings. Such weight is almost entirely supported by a steel water pipe collection box and stave cooler support (hereinafter, “pipe box”) 116 that protrudes from the backside of each stave cooler 108, 110, and 112.
In the top left corner of
These two bolts 119 are long enough to be run completely through pipe box 115 and to be fastened with nuts 120 to a winch line draw plate 121. Such lifting plate 118, bolts 119, nuts 120, and winch line draw plate 121 should already be assembled when the stave cooler 108 is lifted up and dangling on the hoist line. The winch line can be slipped through penetration 116 to draw it out and into place for welding.
All such pieces are reusable, except bolts 119 which get punched in from the outside (after removing nuts 120 and draw plate 121) to fall down to the bottom on the inside. The holes left behind are then plugged up or otherwise filled from the outside. The bolt holes left behind could also be used for thermocouples and wear monitor probes with appropriate packing and sealing.
Since stave coolers 108, 110, and 112 do not all hang the same vertically inside BF 100, their respective pipe boxes 115 must be set at a different angle for each such that all the plumbing exiting from them will be level after installation in the shell 114. Therefore, three variations of pipe box 115 are needed, stave coolers 108 require a pipe box 122, stave coolers 110 require a pipe box 123, and stave coolers 112 require a pipe box 124.
A number of independent loops of MONEL-400, for example, water pipe are cast into every stave cooler 108, 110, and 112. Other embodiments may use copper-nickel instead of MONEL-400. A single group 126 of water inlets and outlets connected internally are routed horizontally out through each respective pipe box 122, 122, and 124. MONEL-400 and copper-nickel water pipe are used instead of ordinary copper tubing in some embodiments because such bonds better to the copper casting being poured and the hot liquid copper will not “burn through” during casting.
A temporary lifting bolt 128 can be fitted into each stave cooler 108, 110, and 112 during installation inside of and on shell 114, e.g., to lift it so lifting plate 118 and bolts 119 can be installed and attached to the hoist line. After it's no longer needed, it can be removed and the inside threaded area plugged. A set of four slip bolts 130 is installed for each stave cooler 108, 110, and 112 from outside shell 114. The four slip bolts 130 are not needed so much to support the weight of each stave cooler 108, 110, and 112 inside shell 114, but are used to hold the stave cooler up against the blast furnace shell. The four slip bolts 130 need to be snug, but should allow for some slippage as will be needed when the stave cooler naturally expands and contracts. Special washers inside or outside, or both, may help this functioning. Once bolts 130 are installed from outside shell 114, a gas-tight cup 132 is welded over the head of each on the outside of shell 114. Lethal carbon monoxide (CO) process gases can leak past otherwise.
Bare water pipe inlet and outlet ends 206 are exposed. In this embodiment, these are sleeved in gas-tight thimbles 208 and enclosed in a pipe box 210. It is possible to not use sleeves at all.
Many other obvious ways exist to bring the water pipe inlet and outlet ends 206 out of pipe box 210 and fit them with pipe couplers 214. The point is to keep process gases contained inside while enabling the coolant plumbing connections outside. So the pipe ends themselves or the couplers can be welded to the thimble cover plate 212 when there is no sleeving. The piping includes 2″ diameter NPT components in this embodiment.
A flexible, thermally conductive material suitable for elevated temperature service may be stuffed inside pipe box 210 before it is sealed up.
Inside, not shown, this particular embodiment has four independent loops of MONEL-400 2″ Schedule-40 pipe that are cast inside copper stave casting body panel 200, together they constitute a pipe circuit. The only parts of that visible in
It is important to gather the inlet and outlet pipe ends 126 closely together into one group per stave. Their common exit through the blast furnace shell 114 can then be “protected” by the one pipe box (120,122,124) from venting dangerous lethal process gases and from the mechanical and thermal stresses associated with having to support the 3,000+ kg weight of an installed stave cooler. Here, in this embodiment, the pipe boxes are made of ASTM A-36 carbon steel, but structural steel, or boiler plate steel are also possible.
Embodiments of the present invention do not cast the pipe boxes into the copper stave casting body panel 200. We ourselves tried doing that with unsatisfactory results. Carbon steel components do not bond well to the copper using conventional methods and can pull out and apart in service. For example, see the “manifold 106” in U.S. Pat. No. 10,222,124, issued Mar. 5, 2019. Steel components do not seal well in gas tight connections to the copper using conventional methods and lethal process gases can leak through the copper made porous at the interface while in service. The molten liquid copper during the casting pour cannot be pushed to well-up high enough inside.
As used herein, the terms “pipe collection box,” collar, or pipe box (120,122,124) are terms that are equivalent to “manifold” and “external manifold.”
A sufficiently strong “manifold” must have the copper casting well up high inside to add the strength needed to support the full weight of the stave cooler.
What makes pushing up the molten copper to well up high inside the “manifold” a bad idea is a so-called shrink-back. The extra thick copper welling up creates hot spots that shrink with cooling so much that the copper will pull off the steel inside.
Supports made of steel can be mechanically locked in by exotic dissimilar metal welding, and/or by entrained liquid copper that passed through and froze inside openings preformed in the steel footer rings.
As represented in
Extraordinary measures are required to be sure the steel footing and foundation frame 202 stays strong and does not ever separate from the copper stave casting body panel 200. Exotic welding methods must be applied to weld steel to copper. Currently, this can only be done by specially equipped and advanced stave foundries. No practical field method or equipment is available.
Mechanical anchoring methods are used herein to lock the carbon steel footing and foundation frame 202 in place within the copper stave casting body panel 200. Openings 204 are placed in the bottom half of the footing and foundation frame 202 such that fingers of molten copper can flow in and freeze during casting to lock the parts together. No bonding of metals is relied upon by this alternative technology, and so the quality of any bonding achieved need not be all that good. Advantageously, the pipe boxes are excluded from the casting processes, and so are not underfoot.
During construction of BF 100, and the installation of any of stave coolers 108, 110, and 112, the job of hanging each inside in its place is highly simplified by the use of only one pipe box 122, 123, 124. Conventional staves often had four inlets widely separated from their corresponding four outlets wherein each was shielded by its own “protection pipe”. Work crews find it much easier while maneuvering the heavy stave cooler to thread through the single pipe box in the blast furnace shell 114.
The stave coolers are lifted up inside blast furnace shell 114 and maneuvered to insert its corresponding pipe box 122, 123, 124 through an appropriate matching penetration. An adapter ring 216 is slipped over and a in-field weld 302 applied. Then a, in-field weld 303. A thimbled cover plate 212 with thimble sleeves is slipped over inlet/outlet pipe ends and welded at the factory with a weld 304 and a weld 305. All welds 301-305 must be continuous and gas-tight in order to contain lethal process gases inside pipe box 122, 123, 124. Fortunately, all welds are simplified by being carbon steel to carbon steel, and so those applied in the field can succeed with conventional equipment.
Returning to
The steel footing and foundation frame 202, and a matching pipe box, could be in the form of a ring and a cylinder in order to facilitate friction welding by spinning carbon steel footing and foundation frame 202 under pressure into the casting 200.
The point is to show openings 204 for copper finger entraining exist all around the bottom lower perimeter of footing and foundation frame 202.
Once each stave cooler 108, 110, and 112 is raised and hung inside shell 114, and its pipe box 122, 123, 124 is pushed all the way through, an adapter plate 210 is slipped over outside and welded on all around for a gas-tight seal. The inside opening dimensions of adapter plate 210 can be tightly controlled economically. More so than trying to get the pipe box penetrations in shell 114 to locate and fit concisely. The adapter plate 210 is a crutch to make installation easier, the pipe boxes themselves can, of course, be directly welded to the pipe box penetrations in shell 114, given the gaps all around are not too wide.
Since each stave cooler 108, 110, and 112 here is made from cast copper, its hot-face will wear rapidly in service if not provided with a protection barrier, layer or liner. Ordinarily this will be common refractory brick walls erected as the inner liners of BF 100 and cooled by stave coolers 108, 110, and 112. Bricks can require some sort of horizontal ribs and grooves with which the bricks can be inserted and retained for a twenty year campaign life.
Stave coolers made of copper need to have a wear resistant barrier installed on their hotfaces. For example, horizontal rows of refractory bricks made of silicon carbide or graphite can be stacked in front of or inserted by various means into an appropriately contoured hotface. The key benefits of StarCeram® S Sintered Silicon Carbide (SSiC) are advertised commercially to include excellent chemical resistance, very high strength, corrosion resistance up to very high application temperatures, excellent mechanical high temperature properties, very good thermal shock resistance, low thermal expansion, very high thermal conductivity, high wear resistance, very high hardness, semiconductor properties. All good things for a stave cooler in a blast furnace.
Simple “bricks” or blocks of cast iron are also expected to function well.
An alternative to bricks is any refractory or shotcrete, which is similar to gunite and is a refractory that is blown onto the hotfaces of stave coolers through high pressure concrete hoses and nozzles. Minerals Technologies Inc. (MiNTEQ) of Bethlehem, Pa., is a commercial producer of shotcrete for blast furnaces. Its rapid installation rates bring down costs and total refractory installation time, they are low-rebound and reduce total consumption, and they are superior refractoriness that increase blast furnace life, and improve fuel efficiency.
A variety of SUPERSHOT™ products are sold worldwide for Blast furnace operations. SUPERSHOT™ AR material suits mid-stack to upper-stack re-linings and repairs. It has excellent abrasion resistance at lower temperatures. Sixty percent alumina silica, low cement bonded shotcrete. Such does not require high-firing temperatures to develop its physical properties and abrasion resistance. SUPERSHOT™ SC15 is 72% alumina silica, 15% silicon carbine with ultra-low cement binder. It is high density, high thermal conductivity, low porosity shotcrete capable of rapid dry out. SUPERSHOT™ BL shotcrete material is suited for the thermal protection of Belly Linings during blow-in. The same shotcrete equipment can be used, with no change over to gunning material and batch guns. Rapid installation rates of over eight tons/hour are possible.
Alternatively, steel anchor frame 514 is welded in with solid state welding technology to achieve very strong, gas-tight bonds with the copper casting. Solid-state welding is defined as a joining process without any liquid or vapor phase, with the use of pressure, and with or without increased temperature. Solid-state welding generally refers to a coalescence that results from the intense application of pressure alone or a combination of heat and pressure. When heat is used, the temperature in the process is kept below the melting point of the metals being welded. No filler metal is used. Representative welding processes include: diffusion welding where two surfaces are held together under pressure at an elevated temperature and the parts coalesce by solid-state diffusion; friction welding where coalescence is achieved by the heat of friction between two surfaces; and, ultrasonic welding where moderate pressure is applied between two parts and an oscillating motion at ultrasonic frequencies is used in a direction parallel to the contacting surfaces. The combination of normal and vibratory forces results in shear stresses intense enough to push aside surface films and produce atomic bonding of the two surfaces.
The life and performance of bricks 600 will be severely curtailed if they do not stay in intimate contact with stave cooler hotface 606 to receive cooling. Gaps, cracks, and spalling can cause excessive heating. It helps if bricks 600 form a tight enough complete horizontal ring row around the inside of BF 100 that they will swell and expand side-to-side enough to press the feet 618 harder into channels 602. A proper selection of materials for brick 600 is therefore required to get an appropriate amount of expansion without crushing or cracking.
The rotate-in-to-lock refractory brick 700 will not function correctly if not used a correct relative orientation to earth's gravity.
Bricks 700 must be installed in complete horizontal ring rows around the interior of BF 100 before proceeding to a next upper row. Any brick installed in a row above would prevent the top 720 from rotating up because it would contact and be stopped by the bottom 724 of the brick above.
The refractory gravity brick 800 will function best if used in a relative orientation to earth's gravity that helps it constantly press its nose 812 deeper into the matching seat 810 as it swells, ages, deteriorates, and shifts over extended periods of operational time.
Bricks 800 are preferred to be installed in complete horizontal ring rows around the interior of BF 100 before proceeding to a next upper row. Any brick 800 installed adjacent to any other brick 800 will not prevent the removal of a damaged brick nor the insertion of a new brick thanks to the favorable geometries.
“Bricks” made of cast iron could be shaped like bricks 700 and 800 and be usefully applied.
The weight of every brick 700 or 800 is pretty much carried by their respective stave coolers 702 and 802 because they each fully rest on the horizontal rows of ledges 706 and upturned ribs 806. This means that wear that thins the bricks from their faces can be allowed to continue years longer because the bricks don't have to support any brickwork above. Sudden collapse is not a problem.
No doubt variations and modifications to the above will occur to artisans that have read and understood our disclosures here. Such variations and modifications are intended to be included in the scope of the Claims that follow.
This application Ser. No., 16/290,922, Claims priority from provisional application, 62/808,857, filed Feb. 22, 2019, now expired. This application Ser. No., 16/290,922, is a Continuation in-part of application Ser. No. 16/101,418, filed Aug. 11, 2018, now U.S. Pat. No. 10,364,475. application Ser. No. 16/101,418 is a Continuation in-part of application Ser. No. 15/815,343, filed Nov. 16, 2017, now U.S. Pat. No. 9,963,754; and claims priority from a provisional application, 62/701,832, filed Jul. 22, 2018, now expired. This application Ser. No., 16/290,922, is a Continuation in-part of application Ser. No., 13/147,996, filed Dec. 23, 2011, now abandoned. application Ser. No., 13/147,996, is a National Stage Entry of PCT/US11/30591, filed Mar. 30, 2011. PCT/US11/30591 Claims priority from a provisional application 61/318,977, filed Mar. 30, 2010, now expired. This application Ser. No., 16/290,922, is a Continuation in-part of application Ser. No. 13/148,003, filed Dec. 23, 2011, now U.S. Pat. No. 10,247,477. application Ser. No. 13/148,003 Claims priority from provisional application 61/319,089, filed Mar. 30, 2010, now expired.
Number | Name | Date | Kind |
---|---|---|---|
2319065 | Karmanocky | May 1943 | A |
2345188 | Foell | Mar 1944 | A |
4768447 | Roumeguere | Sep 1988 | A |
4809621 | Materna | May 1989 | A |
5426664 | Grove | Jun 1995 | A |
6126893 | Otsuka | Oct 2000 | A |
6280681 | MacRae | Aug 2001 | B1 |
8834784 | MacRae | Sep 2014 | B2 |
9963754 | MacRae | May 2018 | B2 |
10222124 | Smith | Mar 2019 | B2 |
20120104670 | Smith | May 2012 | A1 |
20120193843 | MacRae | Aug 2012 | A1 |
20130203007 | Smith | Aug 2013 | A1 |
20150377554 | Smith | Dec 2015 | A1 |
20180149429 | Smith | May 2018 | A1 |
20190154338 | Smith | May 2019 | A1 |
Number | Date | Country |
---|---|---|
2934453 | Mar 1981 | DE |
0025132 | Mar 1981 | EP |
148611 | Sep 1977 | GB |
2011123579 | Oct 2010 | WO |
2011123568 | Sep 2012 | WO |
WO-2014121213 | Aug 2014 | WO |
2014121213 | Aug 2015 | WO |
Entry |
---|
Joubert Analysis of Blast Furnace Lining/Cooling Systems Using Computational Fluid Dynamics by Hugo Joubert, A Thesis at the Rand Afrikaans University, Nov. 1997 (herein Joubert). |
METEC2011 White Paper delivered Jun. 30, 2011, in Dusseldorf, Germany, by Todd G. Smith and Allan J. Macrae, Authors. Titled “New Method of Lining a Blast Furnace”. |
Number | Date | Country | |
---|---|---|---|
20190271049 A1 | Sep 2019 | US |
Number | Date | Country | |
---|---|---|---|
62808857 | Feb 2019 | US | |
62701832 | Jul 2018 | US | |
61318977 | Mar 2010 | US | |
61319089 | Mar 2010 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 13148003 | Dec 2011 | US |
Child | 16290922 | US | |
Parent | 16101418 | Aug 2018 | US |
Child | 13148003 | US | |
Parent | 15815343 | Nov 2017 | US |
Child | 16101418 | US | |
Parent | 16290922 | US | |
Child | 16101418 | US | |
Parent | 13147996 | US | |
Child | 16290922 | US |