Classifications

• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B22—CASTING; POWDER METALLURGY
  • B22D—CASTING OF METALS; CASTING OF OTHER SUBSTANCES BY THE SAME PROCESSES OR DEVICES
  • B22D11/00—Continuous casting of metals, i.e. casting in indefinite lengths
  • B22D11/04—Continuous casting of metals, i.e. casting in indefinite lengths into open-ended moulds
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B22—CASTING; POWDER METALLURGY
  • B22D—CASTING OF METALS; CASTING OF OTHER SUBSTANCES BY THE SAME PROCESSES OR DEVICES
  • B22D11/00—Continuous casting of metals, i.e. casting in indefinite lengths
  • B22D11/04—Continuous casting of metals, i.e. casting in indefinite lengths into open-ended moulds
  • B22D11/041—Continuous casting of metals, i.e. casting in indefinite lengths into open-ended moulds for vertical casting
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B22—CASTING; POWDER METALLURGY
  • B22D—CASTING OF METALS; CASTING OF OTHER SUBSTANCES BY THE SAME PROCESSES OR DEVICES
  • B22D11/00—Continuous casting of metals, i.e. casting in indefinite lengths
  • B22D11/04—Continuous casting of metals, i.e. casting in indefinite lengths into open-ended moulds
  • B22D11/0401—Moulds provided with a feed head

Definitions

• the invention relates to continuous casting in charge of metals, in particular steel. It relates more specifically to the casting of elongated products, in particular of large section, such as slabs, more commonly called "flat products”.
• continuous casting under load can be considered as an evolution of the conventional continuous casting process, which aims to offset the height of the mold where the solidification of the cast metal begins by contact with the face. inside of the wall of cooled copper, from the place, located above, where the free surface of the poured liquid metal is located (the "meniscus").
• the first solidification proceeds from a very sensitive physical mechanism, at the same time as it constitutes an essential factor in the quality of the product obtained. Thanks to the separation of the levels specific to the continuous casting under load, this solidification takes place in a calm place in terms of hydrodynamics, far from the always disturbed area that is the meniscus region.
• this separation of the two levels is achieved by overcoming the cooled copper body of the ingot mold by an attached non-cooled extension made of refractory material with high thermo-insulating properties (a counterweight in a way), well aligned internally with the ingot mold and at within which the color will place and maintain the meniscus of the cast steel, spilled from a distributor arranged above.
• This intermediate piece must in fact be both good enough heat insulator to maintain the molten steel in the liquid state that it will contain, like the riser, and have good mechanical resistance properties for preserve the geometry of the upper edge of the copper wall on which it rests for as long as possible, precisely where the solidification of the cast metal begins.
• a material like SiAION® responds fairly well to this type of opposite requirement.
• the object of the present invention is to provide a simple, reliable and economical response to the aforementioned difficulties encountered with the casting of products of large cross section.
• the subject of the invention is a mold head for vertical continuous casting in charge of metals, in particular steel, comprising an extension made of heat-insulating refractory material which overcomes the cooled metal crystallizer of the mold (generally made of copper or a copper alloy) by being aligned internally with it, and comprising, between the enhancer and the crystallizer, an insert made of dense refractory material having properties of mechanical resistance (of the SiAION for example) and shaped into a ring so as to be able to match the inner periphery of the mold, characterized in that said insert consists of bars, each bar being formed from a rigid assembly of contiguous juxtaposed and aligned elements, kept clamped together by a clamping means integrated into said bar, and in that means for aligning said bar with the body of the mold are provided and constituted by a pusher associated with a positioning stop formed on the body of cooled copper and against which abuts said assembly subjected for this purpose to the action of the pusher which tends to
• the integrated clamping means is constituted by a transverse threaded tie rod in the long direction associated with clamping nuts (more generally clamping pads) provided at least in abutment on the front face free of the elements located at each end of the assembly.
• the tie rod is placed in an eccentric position towards the "cold" face of the assembly, that is to say its rear face opposite to the "hot” front face intended to be brought into contact with the molten metal to flow.
• the assembly of constituent elements of the insert is provided, in addition to the aforementioned overall tightening means, with mechanical stiffening means of the "cold" face
• the invention consists, in its essential characteristics, in building a long rectilinear compact refractory bar (which we will assume to be SiAION thereafter to fix ideas) from elements, possibly identical, by all surfaces if necessary to allow their watertight junction, of course, and placed end to end one after the other over a distance corresponding to the length desired for the bar, then assembled into a whole made rigid using means own clamping devices designed to also provide mechanical reinforcement of the assembly.
• FIG. 1 is a vertical sectional view of the head of a continuous steel slab casting machine according to the invention, taken along the median plane perpendicular to the large faces of the mold;
• FIG. 1 is a sectional view from above along the cutting plane A-A of Figure 1.
• the head of a Continuous Casting Machine with Vertical Load of steel slabs has, in the direction of extraction of the metal to be produced PI, that is to say i.e. from top to bottom in the figure, a distributor 1 containing a metal bath molten 2, which it distributes to one (or more) ingot mold 3 placed below by means of one (or more) submerged nozzle 4, the lateral outlet openings 5 of the metal of which emerge at about ten cm below the surface free 6 (or "meniscus") of the liquid metal present in the mold 3.
• This mold comprises, as can be seen, two stages 7 and 8.
• the lower stage 7 constitutes the crystallizer, also called “body” of the mold.
• This body of copper, or more generally of a copper alloy, cooled by circulation of water has an interior passage 9 for the cast metal, in which the latter in contact with the cold metal walls will gradually solidify from the periphery to the center at as the PI cast progresses downward within the mold.
• the crystallizer 7 is itself preferably formed of two superimposed parts: a main part 10, extended from above by an accessory part 1 1 well adjusted and aligned internally with the lower part 1 0 to offer the cast product a regular and continuous passage .
• the lower part 1 0 is conventionally constituted in the case of the continuous casting of slabs by four plates (or walls) assembled at right angles: two large walls 12 and 1 2 'facing each other and two small walls end, not visible in the figure. These four walls, the inner face of which is intended to come into contact with the cast metal, are energetically cooled by circulation of water along their outer face.
• a steel jacket 1 3 is provided at a short distance from each plate 1 2, 1 2 ′, for channeling a blade of water 14 preferably with vertical circulation.
• the jacket 1 3 has at its ends passages 1 5 and 1 5 'which put the blade of water 14 in communication with an introduction chamber 1 6 and with an evacuation chamber 1 7 located above, delimited by a external partition 1 8 placed at a distance behind the jacket 1 3.
• the upper attached part 1 1 forms a ring cooled by an internal circulation of water in a channel 1 9 arranged as close as possible to its upper edge 20 on which the solidification of the cast metal will be initiated.
• the role of the ring 1 1 is precisely to thermally protect this edge 20 which will be very thermo-mechanically stressed during casting by cooling it substantially more effectively than the blade cooling circuit can do.
• the cooled ring 1 1 is surface at its base so as to closely match the upper surface of the tubular assembly 1 0 on which it rests, and thus avoid any risk of infiltration of molten metal.
• the upper stage 8 is formed by an extension in uncooled refractory material, the inner wall of which, for the same reasons as above, is preferably aligned with that of the body of the crystallizer 7 (and in any case, not indented).
• the assembly "cooled metallic crystallizer 7 surmounted by the insulating refractory riser 8" defines a calibrating passage for the cast metal PI, the upper portion 21 of which within the riser constitutes a buffer zone for confining the hydrodynamic disturbances caused by the arrival of the molten metal in the ingot mold through the openings 5 of the nozzle 4, and whose portion 9, which extends it downwards, is a solidification zone for the cast metal.
• This solidification is initiated from the first contact of the cast steel with the cold metal wall of the crystallizer 7, namely on the upper edge 20 of the copper ring 11, and continues towards downstream by forming a solid crust 22 whose thickness increases from the periphery towards the center.
• the crust 22, a little more than a centimeter thick is strong enough to withstand the ferrostatic pressure of the still liquid core and continues its centripetal growth until complete solidification of the product cast PI under the effect of water spray bars, not shown, located in the lower half of the machine.
• the product obtained is cut in sections of desired length (slabs) which are then available for further processing (rolling, etc.)
• this refractory riser 8 is also formed by two separate superimposed elements: - an upper sleeve 23 made of refractory material chosen for its heat-insulating qualities, because this is to avoid any premature parasitic solidification of the cast metal in the turbulence zone 21.
• an upper sleeve 23 made of refractory material chosen for its heat-insulating qualities, because this is to avoid any premature parasitic solidification of the cast metal in the turbulence zone 21.
• a fibrous refractory for example the material sold under the name A 120K by the firm KAPYROK.
• a material such as SiAION (Sialon (R)), advantageously doped with boron nitride, may be perfectly suitable.
• This circuit comprises an annular slot 25 formed at the riser - crystallizer interface and opening out at one end on the inner periphery of the ingot mold and connected at its other end to a distribution chamber 26 supplied with argon by a calibrated tube 27, itself connected to a source of argon not shown by means of a box under pressure 28 enveloping the riser 8.
• This arrangement has the advantage of avoiding any risk of oxidation of the liquid metal poured into the mold by the oxygen of the air through the insulating refractory mass 23 inevitably permeable some little.
• the SiAION 24 insert is not made in one piece, but produced from juxtaposed contiguous elements held rigidly clamped together by a clamping means integrated into the insert.
• Figure 2 shows a bar constituting the insert as it appears on each of the large faces of the mold.
• the insert goes around the inner periphery of the mold. It therefore has, once mounted, in the form of a rectangular frame whose sides, small or large, are formed by straight bars conforming to that, 29, shown in FIG. 2.
• a bar 29 is formed by assembling juxtaposed contiguous elements 30 held rigidly clamped together by a clamping means integrated into the bar itself.
• this clamping means specific to the bar is a flange composed of a tie rod passing right through each element passing through a passage 32 provided for this purpose in each of them, this tie rod, threaded to at its ends protruding from the assembly, is associated with clamping nuts 33 screwed onto these ends so as to come to bear on the free front faces of the elements 30 at the end.
• Such a clamping means is said to be “global action” because, like a vice, it puts all the elements into mechanical compression by acting only on the elements at the end of the bar.
• the tie rod is in an offset position towards the “cold” side of the bar (towards the bottom of the figure).
• the face of the insert opposite to it and therefore the least thermally stressed is called a "cold face”.
• the purpose of the offset of the location of the tie rod 32 towards this cold face is to prevent the tie rod, generally made of steel, from overheating by being too close to the hot face, which would result in possible decohesion of the whole following phenomena of too large differential expansion.
• Such preferential compression of the cold face presents another advantage.
• the refractory insert 24 is by destination a transition piece between the cooled metallic crystallizer 7 and the insulating refractory sleeve 23, it is necessarily a poor conductor of heat. There will therefore always be a significant thermal gradient between its hot face and its cold face. It will therefore always also be the seat of significant differential expansion phenomena in its thickness.
• a preferential compression prestressing of its cold face will thus help to counteract the tendency to crack later, which otherwise could be caused by its pulling during the expansion of the hot face in contact with the molten metal.
• the eccentricity of the tightening tie 31 still has the additional advantage of being able to reduce the thickness of the insert 24 if necessary, for example during reconditioning operations on the hot face after use.
• means for stiffening the cold face of the bar are provided.
• This function can be performed simply by a shell 34 better visible in FIG. 2.
• This shell in the shape of an "L” at a slightly acute angle is made of spring steel: the bottom plate 35 is applied tightly against the cold face. of the bar while being held there elastically by its lateral cheek 36 anchored in the material of the insert 24 by means of its folded edge 37 engaged in a notch provided for this purpose on the lateral face (here the upper face) of the bar.
• the correct positioning of the bar 29 within the ingot mold consists in allowing its hot face 36 to come flush with the interior surface of the ingot mold and this in a very regular manner over its entire length, which can reach and even exceed 1.5 m, depending on the width of the poured slab.
• this result is achieved by means of alignment of the bar which consists in permanently pushing it elastically towards the inside of the ingot mold against a retainer secured to the upper copper ring 1 1 of the crystallizer 7.
• such means can be simply constituted, on the one hand, by a coil of springs 38 placed opposite the cold face of the bar and on which the springs act by taking their fixed support on the partition of the box 28, and, on the other hand, by a stopper 39 come by machining of the upper face of the cooled ring 1 1.
• this stop is has the form of a tongue so as to constitute at the same time a partition delimiting the chamber 26 for distributing the flow of argon opening onto the inner periphery of the ingot mold just below the refractory insert 24.
• the underside of the bar 29 must also be machined in correspondence to provide a shoulder 40 visible in the view of FIG. 1 coming to cooperate with the stop 39.
• the unitary elements 30 constituting a bar 29 there is no limitation in the number or the length of the unitary elements 30 constituting a bar 29, and which can moreover all be of the same length or not. Similarly, if it is considered preferable to a single bar, several bars such as 24 can be placed end to end to occupy the width of a large face of the mold.
• the invention applies to the continuous casting not only of steel, but any other metal capable of being continuously cast, and in particular metals with a lower melting point than steel, such as aluminum or copper.

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• Engineering & Computer Science (AREA)
• Mechanical Engineering (AREA)
• Continuous Casting (AREA)
• Molds, Cores, And Manufacturing Methods Thereof (AREA)
• Confectionery (AREA)
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• Tunnel Furnaces (AREA)

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• 1997
  • 1997-06-12 FR FR9707413A patent/FR2764533B1/fr not_active Expired - Fee Related
• 1998
  • 1998-05-26 BR BR9810612-0A patent/BR9810612A/pt not_active IP Right Cessation
  • 1998-05-26 DE DE69803071T patent/DE69803071T2/de not_active Expired - Lifetime
  • 1998-05-26 EP EP98925779A patent/EP0989918B1/de not_active Expired - Lifetime
  • 1998-05-26 WO PCT/FR1998/001042 patent/WO1998056521A1/fr not_active Ceased
  • 1998-05-26 AU AU77762/98A patent/AU7776298A/en not_active Abandoned
  • 1998-05-26 RU RU2000100987/02A patent/RU2198764C2/ru not_active IP Right Cessation
  • 1998-05-26 ES ES98925779T patent/ES2165168T3/es not_active Expired - Lifetime
  • 1998-05-26 PT PT98925779T patent/PT989918E/pt unknown
  • 1998-05-26 JP JP50170299A patent/JP4068163B2/ja not_active Expired - Fee Related
  • 1998-05-26 US US09/424,560 patent/US6318449B1/en not_active Expired - Lifetime
  • 1998-05-26 KR KR10-1999-7011669A patent/KR100540022B1/ko not_active Expired - Fee Related
  • 1998-05-26 CA CA002291593A patent/CA2291593C/fr not_active Expired - Fee Related
  • 1998-05-26 CN CN98806106A patent/CN1086613C/zh not_active Expired - Fee Related
  • 1998-05-26 AT AT98925779T patent/ATE211037T1/de active

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