REFRACTORY RING AND REFRACTORY RING SYSTEM AND METHODS FOR ASSEMBLING THE SAME

Abstract

A unitary refractory ring having a sidewall surrounding and spaced from a center axis, and one or more lifting lugs distributed around the center axis. The lifting lugs extend from an inner face of the sidewall towards the center axis, and are located between lower and upper axial faces of the sidewall. Each lifting lug has a lower lug face extending radially towards the center axis from the inner face of the sidewall, and a backing structure extending upwards along an axial direction from the lower lug face towards the upper axial face of the sidewall. An assembly of refractory rings, and methods for making and assembling refractory rings are also provided.

Claims

1-25. (canceled)

26. A replaceable refractory ring-shaped liner adapted for lifting and placement within a cavity of a metallurgical vessel to form a section of an inner wall of the metallurgical vessel, the ring-shaped liner comprising: a continuous top surface; a continuous bottom surface; a continuous arcuate inner surface extending from the top surface to the bottom surface and defining a cavity, wherein the inner surface contacts material that is disposed within the metallurgical vessel; and a continuous arcuate outer surface opposite the inner surface and extending between the top surface and the bottom surface; wherein the inner surface comprises a plurality of protrusions intermediate the top surface and the bottom surface and extending into the cavity; wherein a plurality of spacings are defined between the protrusions of the plurality of protrusions; and wherein the ring-shaped liner comprises a heat resistant, refractory material and is configured to prevent passage of molten material through the inner surface to the outer surface.

27. The ring-shaped liner of claim 26, wherein the plurality of protrusions includes at least three protrusions.

28. The ring-shaped liner of claim 26, wherein the protrusions of the plurality of protrusions are disposed along the inner wall at generally the same elevation above the bottom surface.

29. The ring-shaped liner of claim 26, wherein each protrusion of the plurality of protrusions has a shape configured for contact with a lifting device configured for lifting the ring-shaped liner.

30. The ring-shaped liner of claim 26, wherein the ring-shaped liner comprises refractory bricks joined together with a bonding agent.

31. The ring-shaped liner of claim 26, wherein at least one protrusion of the plurality of protrusions comprises one or more refractory bricks protruding from the inner surface into the cavity.

32. The ring-shaped liner of claim 26, wherein at least one protrusion of the plurality of protrusions is formed by one or more refractory bricks comprising a thickness dimension greater than a thickness dimension of adjacent refractory bricks in the ring-shaped liner.

33. The ring-shaped liner of claim 26, wherein the ring-shaped liner comprises at least one of a precast shape and a monolithic shape.

34. The ring-shaped liner of claim 26, wherein at least one protrusion of the plurality of protrusions comprises at least one of a precast shape and a monolithic shape.

35. A replaceable refractory ring-shaped liner adapted for lifting and placement within a cavity of a metallurgical vessel to form a section of an inner wall of the metallurgical vessel, the ring-shaped liner comprising: a continuous top surface; a continuous bottom surface; a continuous arcuate inner surface extending from the top surface to the bottom surface and defining a cavity, wherein the inner surface contacts material that is disposed within the metallurgical vessel; and a continuous arcuate outer surface opposite the inner surface and extending between the top surface and the bottom surface; wherein the inner surface comprises a continuous protrusion intermediate the top surface and the bottom surface and extending into the cavity; and wherein the ring-shaped liner comprises a heat resistant, refractory material and is configured to prevent passage of molten material through the inner surface to the outer surface.

36. The ring-shaped liner of claim 35, wherein the continuous protrusion has a shape configured for contact with a lifting device configured for lifting the ring-shaped liner.

37. The ring-shaped liner of claim 35, wherein the ring-shaped liner comprises refractory bricks joined together with a bonding agent.

38. The ring-shaped liner of claim 35, wherein the protrusion comprises one or more refractory bricks protruding from the inner surface into the cavity.

39. The ring-shaped liner of claim 35, wherein the protrusion comprises one or more refractory bricks comprising a thickness dimension greater than a thickness dimension of adjacent refractory bricks in the ring-shaped liner.

40. The ring-shaped liner of claim 35, wherein the ring-shaped liner comprises at least one of a precast shape and a monolithic shape.

41. The ring-shaped liner of claim 35, wherein the protrusion comprises at least one of a precast shape and a monolithic shape.

42. A metallurgical vessel comprising an inner refractory wall including at least one ring-shaped liner as recited in claim 26.

43. A metallurgical vessel comprising an inner refractory wall including at least one ring-shaped liner as recited in claim 35.

44. A method for providing or replacing all or a section of a refractory inner wall or liner of a metallurgical vessel, the method comprising: lifting a ring-shaped liner as recited in claim 26 into a cavity defined by components of a metallurgical vessel; and positioning the ring-shaped liner to form at least a portion of a refractory inner wall or liner of the metallurgical vessel.

45. The method of claim 44, wherein the lifting comprises contacting a surface of a protrusion on the inner wall of the ring-shaped liner with a lifting device and lifting the ring-shaped liner.

46. The method of claim 44, wherein the lifting and the positioning are repeated for a plurality of the ring-shaped liners to form at least a portion of the inner refractory wall or liner of the metallurgical vessel.

47. A method for providing or replacing all or a section of a refractory inner wall or liner of a metallurgical vessel, the method comprising: lifting a ring-shaped liner as recited in claim 35 into a cavity defined by components of a metallurgical vessel; and positioning the ring-shaped liner to form at least a portion of a refractory inner wall or liner of the metallurgical vessel.

48. The method of claim 47, wherein the lifting comprises contacting a surface of the protrusion on the inner wall of the ring-shaped liner with a lifting device and lifting the ring-shaped liner.

49. The method of claim 47, wherein the lifting and the positioning are repeated for a plurality of the ring-shaped liners to form at least a portion of the inner refractory wall or liner of the metallurgical vessel.

50. A replaceable refractory ring-shaped liner adapted for lifting and placement within a cavity of a metallurgical vessel to form a section of an inner wall of the metallurgical vessel, the ring-shaped liner comprising: a continuous top surface; a continuous bottom surface; a continuous arcuate inner surface extending from the top surface to the bottom surface and defining a cavity, wherein the inner surface contacts material that is disposed within the metallurgical vessel; and a continuous arcuate outer surface opposite the inner surface and extending between the top surface and the bottom surface; wherein the inner surface comprises a plurality of protrusions intermediate the top surface and the bottom surface and extending into the cavity; wherein a plurality of spacings are defined between the protrusions of the plurality of protrusions; wherein the ring-shaped liner comprises a heat resistant, refractory material; and wherein the ring-shaped liner comprises refractory bricks joined together with a bonding agent.

51. The ring-shaped liner of claim 50, wherein at least one protrusion of the plurality of protrusions comprises one or more refractory bricks protruding from the inner surface into the cavity.

52. A replaceable refractory ring-shaped liner adapted for lifting and placement within a cavity of a metallurgical vessel to form a section of an inner wall of the metallurgical vessel, the ring-shaped liner comprising: a continuous top surface; a continuous bottom surface; a continuous arcuate inner surface extending from the top surface to the bottom surface and defining a cavity, wherein the inner surface contacts material that is disposed within the metallurgical vessel; and a continuous arcuate outer surface opposite the inner surface and extending between the top surface and the bottom surface; wherein the inner surface comprises a continuous protrusion intermediate the top surface and the bottom sur-face and extending into the cavity; wherein the ring-shaped liner comprises a heat resistant, refractory material; and wherein the ring-shaped liner comprises refractory bricks joined together with a bonding agent.

53. The ring-shaped liner of claim 52, wherein at least one protrusion of the plurality of protrusions comprises one or more refractory bricks protruding from the inner surface into the cavity.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0060] The following drawings are provided to help explain embodiments described herein, and are not intended to limit the scope of the appended claims. Like reference numbers refer to like features.

[0061] FIG. 1 is an isometric view of a first exemplary embodiment of a unitary refractory ring.

[0062] FIG. 2 is an elevation view of the refractory ring of FIG. 1.

[0063] FIG. 3 is a top plan view of the refractory ring of FIG. 1.

[0064] FIG. 4 is a partial section view of the refractory ring of FIG. 1, shown in elevation view along line IV-IV of FIG. 3, with background removed.

[0065] FIG. 5 is a top plan view of a lifting brick layer of the embodiment of FIG. 1.

[0066] FIG. 6 is a top plan view of a backing brick layer of the embodiment of FIG. 1.

[0067] FIG. 7 is a partial section view of another exemplary embodiment of a refractory ring showing a portion of the sidewall in elevation view, with background removed.

[0068] FIG. 8 is a partial section view of another exemplary embodiment of a refractory ring showing a portion of the sidewall in elevation view, with background removed.

[0069] FIG. 9 is a partial section view of another exemplary embodiment of a refractory ring showing a portion of the sidewall in elevation view.

[0070] FIG. 10 is a partial section view of another exemplary embodiment of a refractory ring showing a portion of the sidewall in elevation view.

[0071] FIG. 11 is a top plan view of another exemplary embodiment of a refractory ring.

[0072] FIG. 12 is a top plan view of another exemplary embodiment of a refractory ring.

[0073] FIG. 13 is a top plan view of another exemplary embodiment of a refractory ring.

[0074] FIG. 14 is an isometric view of another exemplary embodiment of a unitary refractory ring.

[0075] FIG. 15 is a partial section view of the refractory ring of FIG. 16 showing a portion of the sidewall in elevation view, with background removed.

[0076] FIG. 16 is an isometric view of another exemplary embodiment of a unitary refractory ring.

[0077] FIG. 17 is a partial section view of the refractory ring of FIG. 16 showing a portion of the sidewall in elevation view, with background removed.

[0078] FIG. 18 is a cross-section elevation view of an exemplary embodiment of a ladle assembly incorporating an exemplary embodiment of a system of unitary refractory rings, shown with background simplified.

[0079] FIG. 19 is an exploded version of FIG. 18.

[0080] FIG. 20 is a cross-section elevation view of another exemplary embodiment of a refractory ring.

DESCRIPTION OF EMBODIMENTS

[0081] Embodiments described herein provide examples of inventions relating to refractory rings, refractory ring systems, and methods for making and assembling the same. It will be understood that these examples are not intended to limit what is claimed, and modifications may be made to these examples without departing from the scope of the appended claims.

[0082] A first exemplary embodiment of a unitary refractory ring 100 is illustrated in FIGS. 1-4. In general terms, the refractory ring 100 is a unitary part that can be manipulated as a unit for transportation and assembly into a refractory lining. As explained below, the refractory ring 100 may be formed using a variety of different construction techniques. In the example of FIGS. 1-4, the unitary refractory ring 100 is formed by an assembly of refractory bricks that are connected together to form a unitary structure.

[0083] The refractory ring 100 has a sidewall 102 that forms a continuous closed loop about a center axis 104 that extends in an axial direction A. The sidewall 102 is spaced from the center axis 104 in a radial direction that is perpendicular to the axial direction A. The sidewall 102 has an inner face 106 that faces towards the center axis 104, and an outer face 108 that faces away from the center axis 104. The inner face 106 and the outer face 108 extend along the axial direction between a lower axial face 110 at the bottom of the sidewall 102, and an upper axial face 112 at the top of the sidewall 102. In the shown embodiment, the lower axial face 110 and upper axial face 112 are flat surfaces extending orthogonally to the center axis 104. While this is preferred, other embodiments of upper axial faces 112 and lower axial faces 110 may include other shapes, such as helical starter ramps for aligning helical rows of bricks.

[0084] As shown in FIG. 3, the closed loop formed by the sidewall 102 has the shape of a circle as viewed along the axial direction A. However, other embodiments may have other shapes, such as elliptical shapes, half circles joined by straight sections, and so on.

[0085] The inner face 106 and outer face 108 also may have any operable shape with respect to the axial direction A. In the example of FIGS. 1-4, the inner face 106 and outer face 108 each extend at a taper angle θ relative to the axial direction A, such that the sidewall 102 forms a frustoconical shape that grows in the radial direction as a function of height. Thus, the refractory ring 100 is wider at the top than at the bottom. As will be appreciated from the illustration of FIG. 4, the inner face 106 and outer face 108 may taper in a stepwise fashion, with the faces of each individual brick being parallel to the axial direction, but the bricks being stacked at progressively greater distances from the center axis 104. The value of the taper angle θ may be selected according to conventional refractory system requirements, as will be understood by persons of ordinary skill in the art.

[0086] In a typical case, the outer face 108 of the refractory ring 100 preferably is dimensioned and shaped to fit within a corresponding outer refractory liner of a ladle to form a conventional two-layer ladle lining. The outer face 108 may be dimensioned and shaped to contact the outer refractory liner at one or more locations, or it may be dimensioned and shaped to be spaced from the outer refractory liner, with a predetermined gap between the outer face 108 and the outer refractory liner. The provision of such a gap permits an intermediate material (e.g. bonding or packing material, intermediate insulating material, and so on) to be placed between the refractory ring 100 and the outer refractory liner. The gap also helps assure that the ring 100 can be properly fit within the outer refractory liner if the dimensions of the outer refractory liner are outside expected specifications.

[0087] The refractory ring 100 also includes lifting lugs 114 distributed around the center axis 104, which are used for lifting and moving the refractory ring 100. Each lifting lug 114 extends from the inner face 106 towards the center axis 104, and has a lower lug face 116 and a backing structure 118 extending upwards along the axial direction A from the lower lug face 116 towards the upper axial face 112. As best shown in FIG. 4, the lifting lugs 114 are located, along the axial direction A, between the lower axial face 110 and the upper axial face 112, and preferably are spaced from the lower axial face 110 to allow access to the lower lug face 116 if the refractory ring 100 is placed on a flat surface. The lower lug faces 116 preferably are all positioned in a single plane and at the same elevation, but this is not strictly required.

[0088] As shown in FIG. 3, the lifting lugs 114 may be distributed equidistantly around the center axis. In this case, there are four lifting lugs 114 spaced at equal 90 degree intervals. However, such equidistant spacing is not strictly required. For example, other embodiments may have uneven spacing in order to place one or more of the lifting lugs 114 out of the path of incoming molten metal material, or to modify the liquid flow dynamics within the ladle. It is also not necessary to have four lifting lugs 114. For example, two lifting lugs 114 on opposite sides of the ring 100 may be removed, leaving two lifting lugs 114 that may be used to lift and move the ring 100.

[0089] In the example of FIGS. 1-4, the lifting lugs 114 are formed by bricks that protrude radially inward from the remainder of the inner face 106 of the sidewall 102. In some embodiments, each lifting lug 114 may be formed by a single brick, but in the shown embodiment, each lifting lug 114 is formed by one or more lower lug bricks 120 and one or more upper backing bricks 122. Each backing brick 122 is located immediately above and in contact (directly or via a connecting structure such as a layer of epoxy, mortar or other adhesive) with one or more of the lug bricks 120.

[0090] As best shown in FIG. 2, the lug bricks 120 and backing bricks are formed as portions of respective brick layers A, B, C, etc. that collectively form the ring 100. The lug bricks 120 and backing bricks 122 preferably have the same heights in the axial direction as the remainder of the bricks forming their respective brick layer, which minimizes assembly difficulty and the need for unique brick sizes. In this example, there are seven brick layers. Layer A is the bottom-most layer, and Layer G is the top-most layer. Layer B incorporates the lower lug brick 120, and is referred herein as a lifting brick layer B. Layer C incorporates the upper backing bricks 122, and is referred to herein as a backing brick layer C. Layers D, E and F are located between the backing brick layer C and the top-most layer G. In other cases, one or more layers may be omitted. For example, one or more of layers C through F may be omitted. One or more of the layers also may be replaced by a monolithic ring-shaped casting of refractory material. For example, layers D through G may be replaced by a single cast layer. Other alternatives and variations will be apparent to persons of ordinary skill in the art in view of the present disclosure.

[0091] Exemplary geometric relationships between the different bricks in the different layers are illustrated in FIGS. 4 through 6. As shown in FIG. 4, the lower brick layer A is defined by a ring of lower bricks 124 that are arranged at a first distance R1 from the center axis 104. That is, the nearest point of each lower brick 124 is spaced from the center axis 104 by the first distance R1. The lifting brick layer B is located above the lower brick layer A with respect to the axial direction A, and is defined by a plurality of lifting layer sidewall bricks 126 arranged in two or more groups at a second distance R2 from the center axis 104, and a plurality of lug bricks 120 arranged in two or more groups at a third distance R3 from the center axis. Each group of lug bricks 120 is located between a respective two of the groups of lifting layer sidewall bricks 126. In this case, there are four groups of lug bricks 120 having two lug bricks 120 in each group, and these groups are interposed between respective pairs of four groups of lifting layer sidewall bricks 126. The upper brick layers D through G are located above the lifting brick layer B with respect to the axial direction A, and each upper brick layer is defined by a ring of upper bricks 128 arranged at a respective fourth distance R4, R4′, R4″, R4′″ from the center axis 104. In this case, R4 is greater than R3, and the upper brick layers have progressively increasing radial distances (i.e., R4<R4′<R4″<R4′″). In other cases, one or more of the upper brick layers may have the same radial distance as the layer below it (i.e., R4 R4′ R4″ R4′″). In some cases, an upper layer also may have a smaller radial distance than the layer below it (see, e.g., FIG. 17).

[0092] As shown in FIG. 5, the third distance R3 is less than the second distance R2, such that each lug brick 120 extends radially inward from the remaining lifting layer sidewall bricks 126. In addition, as shown in FIG. 4, the third distance R3 is less than the first distance R1, such that each lug brick 120 extends radially inward from the lower bricks 124. Thus, each lug brick 120 extends in the radial direction from a respective embedded end 120′ that is embedded in the sidewall 102, to a respective cantilevered end 120″ that extends a first distance (i.e., R3-R1) from the lower adjacent portion of the inner face 106 of the sidewall 102. The cantilevered end 120″ forms at least a portion of the backing structure 118 of the lug 114, and the lower lug face 116 is formed by the exposed lower surface of the cantilevered end 120″.

[0093] The particular geometry of the lower lug face 116 may be selected as necessary to engage an associated lifting device. For example, each lower lug face 116 may be flat and lie in a plane that extends orthogonally to the axial direction A. In the embodiment of FIG. 4, each lower lug face 116 also extends perpendicular to the adjacent portion of the inner face 106, but this is not strictly required (as an alternative, see the embodiment of FIG. 9).

[0094] The embedded end 120′ of the lug brick 120 may extend to be flush with the outer face 108 of the sidewall 102, such as shown in FIGS. 4 and 5. This provides stable securement and a continuous outer face 108, but requires the use of a lug brick 120 having a different geometry than the lifting layer sidewall bricks 126. This construction is not strictly required, and other embodiments may use lug bricks 120 that are identical to the lifting layer sidewall bricks 126 in shape and size, or that have other shapes and sizes.

[0095] The first distance R1, second distance R2 and fourth distance R4 may be selected to provide different ring profile shapes. In the example of FIG. 4, the first distance R1 is less than the second distance R2, and the second distance R2 is less than the fourth distance R4 of the lowermost upper layer D. Thus, the lower layer A, lifting brick layer B and lowermost upper layer D form a conical shape. Additional layers, such as the backing brick layer C (if used) and other upper layers E, F, G may have similar varying dimensions to form a continuous stepped conical shape, such as shown. In other cases, the first distance R1, second distance R2 and fourth distances R4 may be equal, to form a cylindrical profile. Other configurations may be used in other cases.

[0096] The exemplary backing brick layer C is located between the lifting brick layer B and the lowermost upper brick layer D. The backing brick layer C is defined by a plurality of backing layer sidewall bricks 130 arranged in two or more groups at a fifth distance R5 from the center axis 104, and a plurality of backing bricks 122 arranged in two or more groups at a sixth distance R6 from the center axis 104. Each group of backing bricks 122 is located between a respective two groups of backing layer sidewall bricks 130. The backing bricks 122 are in direct contact with at least one of the plurality of lug bricks (i.e., brick-to-brick contact or contact via an adhesive or bonding layer). Thus, the backing bricks 122 buttress the lug bricks 120 against vertical loads.

[0097] The sixth distance R6 is less than the fifth distance R5, and greater than the third distance R3. Thus, each backing brick 122 extends radially inward from the adjacent backing layer sidewall bricks 130, but does not extend inward as far as the lug bricks 120. In this configuration, each lug 114 is formed by a connected group of lug bricks 120 and backing bricks 122. The lug bricks 120 form a lower portion of the lug backing structure 118. This lower portion extends upwards from the lower lug face 116, and inwards a first distance (R3-R1) from a lower adjacent portion of the inner surface 106. The backing bricks 122 form an upper portion of the lug backing structure 118, and this second portion extends a second distance from the inner surface, with the second distance being less than the first distance. The radially-innermost portions of the first portion formed by the lug bricks 120 and the second portion formed by the backing bricks 122 are parallel to adjacent portions of the inner surface 106, to thereby form a backing structure 118 having a stepped shape, as shown in FIG. 4.

[0098] The configuration of lug bricks 120 and backing bricks 122 may be selected to enhance the load-bearing capacity of the lug 114. For example, in the shown embodiment, each group of backing bricks 122 is centered on the adjacent group of lug bricks 120, and subtends a larger angle, as viewed along the axial direction A, than the adjacent group of lug bricks 120. Such an arrangement can be readily formed by, for example, positioning three backing bricks 122 over two lug bricks 120, with each lug brick 120 contacting two adjacent backing bricks 122. Thus, the backing bricks 122 are positioned to distribute vertical forces applied to the lower lug face 116 both vertically and laterally to spread such loads across a greater number of upper layer bricks 130. In other cases, multiple backing brick layers C may be vertically stacked, with the respective backing bricks 122 of each layer being positioned to buttress the backing bricks 122 of the lower layer against vertical loads. Other alternatives and variations will be apparent to persons of ordinary skill in the art in view of the present disclosure.

[0099] FIGS. 7 through 10 show various alternative embodiments of sidewall and lug structures. In FIG. 7, the sidewall 102 is formed similarly to the embodiment of FIGS. 4-6, however, the lower bricks 124, lifting layer sidewall bricks 126, upper bricks 128 and backing layer sidewall bricks 130 are all positioned at the same distance R1 from the center axis 104. Thus, the inner face 106 of the sidewall 102 forms a cylindrical shape. The bricks also may be configured such that the outer face 108 also forms a cylindrical shape, but this is not required.

[0100] The embodiment of FIG. 8 is also similar to that of FIGS. 4-6, but, in this case, the backing layer is omitted and replaced by another upper layer. In addition, the lug bricks 120 of this or other embodiments optionally may have tapered inner faces 132 that vary from a relatively small third distance R3′ at a lower edge adjacent to the lower lug face 116, to a relatively large third distance R3″ at an upper edge opposite the lower lug face 116. Thus, the lug bricks 120 form a backing structure that tapers towards the inner face 106 as the lug 114 extends upwards. This configuration may reduce wear and turbulence as molten metal strikes the lug 114.

[0101] FIG. 9 shows another embodiment in which the sidewall 102 comprises a monolithic structure formed, for example, by a cast refractory material. The lifting lugs 114 are formed separately from the sidewall 102. The lifting lugs 114 may be cast in place in the desired locations by forming openings or pockets in the sidewall 102 to receive the lugs 114, then casting the lifting lugs into a mold placed over such pockets or openings. Alternatively, the sidewall 102 may be cast with the pocket during the molding process, or later machined to create the pocket, and a preformed lug 114 may be inserted into the pocket. As another example, the lifting lugs 114 may be pre-formed and the sidewall 102 molded around the lifting lugs 104.

[0102] FIG. 10 shows an embodiment in which the sidewall 102 and lug 114 are monolithically formed together as a single part. FIG. 10 also shows the inner face 106 being tapered, and the outer face 108 being cylindrical. Here, the lug 114 extends orthogonally to the axial direction A, but the lower and upper faces of the lug 114 are angled relative to the immediately adjacent portions of the inner face 106. extends at an acute angle In other cases, the outer face 108 may be tapered, and the inner face 106 cylindrical.

[0103] FIGS. 11-13 show further variations in the number, shape and position of the lugs 114 relative to the sidewall 102. In FIG. 11, there are three lugs 114 centered at 120 degree angles from each other. In FIG. 12, there are two lugs 114 at 180 degrees from each other, and each lug 114 is relatively large. In FIG. 13, there is a single lug 114, which may extend entirely around the circumference of the ring 102, as shown, or it may extend around part of the circumference (e.g., a portion of the lug 114 may be omitted to allow unobstructed access for a lifting tool or metal flow). In the cases of FIGS. 12 and 13, each lug 114 may be used as multiple contact points for a lifting mechanism. For example, a lifting mechanism having three lifting arms may be positioned with two of the lifting arms in contact with one lug 114 of FIG. 12, and one lifting arm in contact with the other lug 114 of FIG. 12.

[0104] Two further variations on unitary refractory rings 100 are illustrated in FIGS. 14-17. These variations may be generally the same as the foregoing embodiments. For brevity only the differences are identified.

[0105] In the embodiment of FIGS. 14 and 15, the refractory ring 100 omits the top-most upper layer G, and adds an additional bottom layer A′ formed by bottom bricks 132 located below and attached to the previously-described lower layer A. The bottom layer A′ is configured to distribute the load of the refractory ring 100 more than the lower layer A. Specifically, the lower bricks 124 have a first thickness X1 as measured along a radial direction R that is orthogonal to the center axis, and the bottom bricks 134 have a second thickness X2 as measured along the radial direction R, and the second thickness X2 is greater than the first thickness X1. Thus, the thicker bottom bricks 134 help distribute the weight of the refractory ring 100 to an underlying surface.

[0106] In the example of FIGS. 14 and 15, the bottom bricks 134 are positioned with their excess thickness extending radially inwards from the inner face profile 106′. In this case, the bottom layer A′ preferably is spaced from the lifting brick layer B by the lower layer A to ensure that the entire lower lug face 116 is accessible to lifting equipment. In other cases, the lower layer A may be omitted, and other provisions made to ensure that the lower lug face 116 is suitably available for lifting the refractory ring 100. For example, the bottom bricks 132 immediately below the lug bricks 120 may be replaced by thinner bricks, or the bottom bricks 134 may be offset radially outwards from the outer face profile 108′. The bottom bricks 134 also may be partially offset both inwardly from the inner face profile 106′ and outwardly from the outer face profile 108′. Other options will be apparent in view of the disclosures herein.

[0107] Referring now to FIGS. 16 and 17, this embodiment of a refractory ring 100 has as top layer G formed by relatively thick top bricks 136. Specifically, the upper layer or layers D, E, F are formed by upper bricks 128 having a third thickness X3 in the radial direction R, and the top bricks 136 have a fourth thickness X4 in the radial direction, with the fourth thickness X4 being greater than the third thickness X3. Thus, the top layer G is suited to concentrate weight from above to the refractory ring 100. The extra thickness of the top bricks 136 also may be helpful to improve their durability if the top bricks 136 are within the slag line of the refractory ladle. As with the embodiment of FIGS. 1-6, this embodiment also preferably includes a lower layer A to provide space for a lifting device to engage the lower lug faces 116 when the refractory ring 100 is sitting on a flat surface. Also, as with the embodiment of FIGS. 14 and 15, the top bricks 136 may have their extra thickness offset inward from the inner face profile 106′ or outward from the outer face profile 108′, or both.

[0108] It will be appreciated that all of the foregoing variations may be used in any suitable combination with each other. For example, a ring 100 formed of laid bricks, such as shown in of FIGS. 1-6, may be formed with a tapered inner face 106 and a cylindrical outer face 108. As another example, the embodiments of FIGS. 14-17 are shown as being unitary refractory rings 100 formed by joined refractory bricks, but they may be constructed as described in relation to FIGS. 9 and 10. Other alternatives and variations will be apparent to persons of ordinary skill in the art in view of the present disclosure. Other alternatives and variations will be apparent to persons of ordinary skill in the art in view of the present disclosure.

[0109] Refractory rings 100 as discussed herein may be used in place of all or a portion of a conventional inner refractory lining formed by assembling individual bricks in place within the ladle itself. This allows more convenient, and potentially safer, assembly of the inner refractory liner, and can increase the replacement and repair speed. It is anticipated that multiple refractory rings 100 may be used in a single ladle. Such refractory rings 100 may be identical to each other, or have different constructions.

[0110] An example of a ladle 138 having multiple refractory rings 100a, 100b, 100c is shown in FIGS. 18 and 19. The ladle 138 comprises a conventional outer shell 140 of steel or other durable material, a conventional outer liner 142 formed by connected refractory bricks, and a conventional bottom liner 144 formed by one or more cast refractory structures. The inner liner is formed by a lower refractory ring 100a that is dimensioned to rest on the bottom liner 144, a middle refractory ring 100b that is dimensioned to rest on the lower refractory ring 100a, an upper refractory ring 100c that is dimensioned to rest on the middle refractory ring 100b, and a stack of slag line bricks 152 that are laid on top of the upper refractory ring 100c. Although three refractory rings 100a, 100b, 100c are shown, other embodiments may have one refractory ring, two refractory rings, or more than three refractory rings.

[0111] Each refractory ring 100 comprises a unitary structure having a respective sidewall 102 with a respective inner face 106 forming a continuous closed loop about a center axis 104. Each sidewall 102 is spaced from a center axis 104 and extends along the respective center axis 104 from a respective lower edge 110 to a respective upper edge 112. Each refractory ring 100 also includes a respective plurality of lifting lugs 114 distributed around the center axis 104 and extending from the respective inner face 106 towards the center axis 104.

[0112] The upper edge 112a of the first refractory ring 100a is configured to abut the lower edge 110b of the second refractory ring 100b to form a closed seam 146. Where a third refractory ring 100c is provided, the upper edge 112b of the second refractory ring 100b may be configured to abut the lower edge 110c of the third refractory ring 100c to form another closed seam 148. The closed seams 146, 148 may be filled with an epoxy adhesive or mortar to secure the first refractory ring 100a to the second refractory ring 100b, but this is not strictly required.

[0113] Similarly, the lower edge 110a of the first refractory ring 100a may rest directly on an upper surface 150 the refractory ladle bottom 144, and the upper edge 112c of the third refractory ring 100c (or the upper edge 112b of the second refractory ring 100b, if there is no third refractory ring 100c) may be configured to abut the stack of slag line bricks 152. The slag line bricks 152 may be provided as another unitary refractory ring, but more preferably are laid in place after the final refractory ring 100 is installed, due to the fact that incorporating protruding lifting lugs 114 into the slag line region could negatively affect fluid flow and might degrade rapidly during use.

[0114] The refractory rings 100 preferably are configured such that they can be connected to each other, and optionally also with the ladle bottom 144 and slag line bricks 152, in any relative angular orientation. For example, the upper edges 112 and lower edges 110 may lie in respective flat planes that are orthogonal to the center axis 104, such as shown in FIGS. 18 and 19 (see also FIGS. 4, 7-10 and 15 and 17). In this configuration, there are no protrusions or recesses in the upper or lower edges 112, 110. Thus, the upper edge 112 of a lower refractory ring 100 may be joined with the lower edge 110 of an upper refractory ring 100 at any angular orientation about the center axis 104. This simplifies the construction of the refractory rings 100 and their assembly into the ladle 138, and is expected to provide a significant benefit over preformed refractory rings having helical starter ramps for laying helical arrangements of bricks above or below the ring. Despite this, one or more of the refractory rings 100 may include such starter ramps or other features. For example, the uppermost refractory ring 100c may have helical starter ramps at the upper edge 112 to facilitate assembly of the slag line bricks 152 in place within the ladle 138.

[0115] FIGS. 18 and 19 also show a configuration of the lifting lugs 114, in which the lifting lugs 114 of each refractory ring 100 are positioned with their lower lug faces between the respective lower edge 110 and the respective upper edge 112. Thus, the lower lug faces are accessible even when the refractory ring 100 is positioned on a flat surface, such as an assembly room or factory floor.

[0116] An alternative arrangement is shown in FIG. 20. Here, the upper edges 112 may be formed as the uppermost edge of an upper radially-tapered surface 112′, and the lower edges 110 may be formed as the lowermost edge of a lower radially-tapered surface 110′. As used herein, a radially-tapered surface is a frustoconical surface that is tapered along the axial direction A as a function of radial distance from the center axis 104. This construction may be provided by adding precast ring layers 154 having the desired bevel to the tops and bottoms of adjacent brick refractory rings, by making the refractory ring sidewall 102 as a casting, such as shown in FIGS. 9 and 10, by machining a conical bevel on the upper and lower bricks of an assembled brick refractory ring, and so on. This construction provides a self-centering function during assembly, and also provides the benefit of allowing installation in any angular orientation.

[0117] The embodiment of FIGS. 18 and 19 has a tapered inner liner that transitions from a relatively small inside diameter at the ladle bottom 144 to a relatively large inside diameter at the slag line bricks 152. In this case, each refractory ring 100 may have different dimensions to form a continuous taper. In other embodiments, the inner surfaces 106 of the refractory rings 100 may have a cylindrical shape with a uniform inside diameter (see FIG. 7 as an example), in which case the refractory rings 100 may have identical constructions. Other alternatives and variations will be apparent to persons of ordinary skill in the art in view of the present disclosure. The refractory rings 100 in FIGS. 18 and 19 also may include variations such as enlarged bottom bricks 134 on the lower refractory ring 100a, and enlarged top bricks 136 on the upper refractory ring 100c.

[0118] Refractory ring systems, such as shown in FIGS. 18 and 19, may be assembled in any suitable order. For example, the ladle 138 may be prepared by installing a base portion 144a of the ladle bottom 144 into the shell 140, then laying the bricks to form the outer liner 142 using conventional methods, then installing an bottom plug 144b, and a bottom ring 144 to complete the ladle bottom 144. Next, the first refractory ring 100a, second refractory ring 100b and third refractory ring 100c are installed one at a time and in that order, by lifting and moving each refractory ring 100 using its respective lifting lugs 114. Finally, the slag line bricks 152 are installed in place on top of the third refractory ring 100c using conventional methods. Other embodiments may use other variations of ladle bottom constructions 144, or other assemblies of refractory rings 100.

[0119] During assembly, one or more of the first refractory ring 100a, second refractory ring 100b, and third refractory ring 100c may be installed at an arbitrary angular orientation about the center axis 104, thus simplifying and accelerating the installation process.

[0120] Embodiments of refractory rings 100 may be constructed using any suitable methods. For example, the refractory ring 100 of FIGS. 1-6 may be constructed by laying each individual brick and joining the bricks as each one is laid with all of the previously-laid adjacent bricks. This may be performed by forming the lower layer A until it is complete, then laying the lifting brick layer B until it is complete, then laying the remaining layers (e.g., the backing brick layer C if used and the upper layers D-G) one by one until the refractory ring 100 is full formed. Alternatively, the lifting brick layer B and other higher layers may be assembled before the lower layer is fully completed. As another alternative, each layer may be pre-assembled and then the layers joined. The bricks may be laid individually, or pre-assembled into connected groups. For example, an assembly of lug bricks 120 and backing bricks 122 may be pre-formed as a unit to be placed into the refractory ring 100. It is also anticipated that the individual bricks may be a laid and then connected after they are laid by activating a bonding agent placed between the bricks during the laying process. Other alternatives and variations will be apparent to persons of ordinary skill in the art in view of the present disclosure.

[0121] The bricks may comprise any suitable refractory materials, provided the materials, as assembled, have sufficient integrity to hold the refractory ring 100 in a unitary state during lifting and movement of the refractory ring 100 by the lugs 114. Similarly, the bricks forming the lugs 114 may include any refractory material having a modulus of rupture sufficient to prevent the material, as assembled, from breaking during lifting. The bricks also may comprise combinations of different refractory materials, such as by using one type of material for the lugs 114, and another type of material for the remaining bricks. A variety of different refractory materials are known in the art, and the selection of an appropriate material will be within the skill of the person of ordinary skill in the art without undue experimentation.

[0122] The bricks may be connected using any suitable adhesive, epoxy, mortar or the like, provided the connection has sufficient strength to allow the entire refractory ring 100 to be lifted and moved by the lugs 114. Such bonding materials are known in the art, and need not be described in detail herein. In one embodiment, the epoxy or other bonding material has shear strength that is equal to or greater than the shear strength of the bricks. The brick connecting process may be selected according to the bonding material. For example, when mortar is used, each brick may be dipped in a bath of the mortar or brushed with mortar prior to laying. As another example, when an epoxy bonding material is used, the epoxy may be injected in place on each brick as it is laid, and/or on previously-laid bricks to which the next brick is going to be placed. Other alternatives and variations will be apparent to persons of ordinary skill in the art in view of the present disclosure.

[0123] In one preferred embodiment, the bricks all have a similar truncated wedge-shaped construction, with the two converging sides of the wedge shape being oriented along lines that converge at a predetermined distance from the brick. Thus, the bricks can be laid with their converging sides adjacent each other to form a ring of a predetermined size. The ring size can be modified by changing the orientation of the wedge angle, or by laying the bricks with slight gaps between them to change the overall diameter of the ring. As shown in FIGS. 5 and 6, the lug bricks 120 and backing bricks 122 (if used) may be generally identical to the remaining bricks, with the exception being that they have a larger the radial dimension. For example, the lug bricks 120 may have a radial dimension of 8 inches, the backing bricks 122 may have a radial dimension of 7 inches, and the remaining bricks 124, 126, 128, 130 may have a radial dimension of 6 inches. In some cases, one or more bricks may be cut to form a layer having the desired diameter dimension.

[0124] It is expected that embodiments as described herein will provide significant benefits in facilitating the assembly of unitary refractory rings, and the installation of unitary refractory rings into a ladle. When manufactured from individual bricks, the shape and size of the refractory ring 100 can be readily adjusted as necessary to fit different installation requirements. The use of individual bricks also allows the use of different bricks in different locations, as needed to address different operating conditions (e.g., different bricks at the slag line or as the lug bricks). The use of lifting lugs that project radially inwards removes the need for creating openings in the sidewall to receive a lifting mechanism, and this helps reduce the generation of stress in the sidewall and avoids creating pockets of inhibited flow where molten metal can recirculate in isolation from the remaining contents of the ladle. Other benefits will be apparent from this disclosure and practice of embodiments.

[0125] The present disclosure provides examples of embodiments of unitary refractory rings and methods for making them and assembling them into ladles. It will be appreciated that embodiments may be modified in various ways, such as described herein or as might otherwise be determined during practice, and such modifications are intended to be included within the scope of this disclosure. Features of any given embodiment described herein may be used in isolation from other features of that embodiment, or in combination with features of other embodiments. Other alternatives and variations will be apparent to persons of ordinary skill in the art in view of the present disclosure.