1. Technical Field of the Invention
The present invention relates to caster rolls used in the manufacturing of sheet material and methods of manufacturing caster rolls. More particularly, the present invention relates to an internally cooled caster roll having one or more layers of material, such as metal, formed on a roll core of the caster roll and methods of manufacturing the caster roll.
2. Description of Related Art
In the manufacture of cast aluminum plate, strip, sheet, or foil (hereinafter referred to as “aluminum sheet material”), conventional roll casting machines used to manufacture such aluminum sheet material typically have a twin-roll arrangement. In the twin-roll arrangement, a pair of substantially parallel, water-cooled, and counter-rotating rolls is used to cast the aluminum sheet material. Generally, after a given period of use, the surface, or roll shell, of these “caster” rolls must be reground and/or repaired because of heat cracks resulting from thermal fatigue and/or out-of-roundness (i.e., eccentricity) due to slipping between the roll core and roll shell. As the roll shell becomes thinner from regrinding, the roll shell surrounding the roll core must be replaced periodically and the roll core repaired before the twin-roll assembly is rebuilt.
It is generally known that the major cause of damage to prior art caster rolls is slipping between the roll core and the roll shell. The roll core in prior art caster rolls typically has circumferential grooves or channels formed in the surface of the roll core. The slipping typically occurs between the grooved or channeled surface of the roll core and the roll shell, which results in the formation of roll gaps between the roll core and roll shell. This leads to the aforementioned out-of-roundness (i.e., eccentricity) problem, which may ultimately result in misshaping the cast aluminum sheet material. Another problem associated with current caster rolls includes cracking in the roll shell due to thermal gradient and accompanying leakage of coolant onto the roll shell, which is a safety concern. Additionally, the thermal gradient along the surface of the roll core and roll core/roll shell slippage often cause the caster roll to distort or bend, which also may result in misshaping the cast aluminum sheet material during production runs.
One approach known in the art for extending the service life of caster rolls is disclosed in U.S. Pat. No. 5,598,633 to Hartz. In the Hartz '633 patent, the surface of the roll core is covered with two overlays of stainless steel each having a distinct hardness. The overlay of stainless steel directly in contact with the surface of the roll core is softer than the second, external overlay of stainless steel. An analogous approach to the foregoing is disclosed in U.S. Pat. No. 5,265,332 also to Hartz. The Hartz '332 patent attempts to extend the service life of the roll core by coating the inner surface of the roll shell with hard chromium.
Internally cooled rolls are well known in the field of continuous sheet casting machines. For example, U.S. Pat. No. 5,279,535 to Hawes et al. discloses an internally cooled caster roll for use in continuous sheet casting applications that includes a plurality of longitudinally extending coolant-conveying bores that extend the length of the caster roll. An annular manifold in the form of an end cap is secured within a recess formed in each end face of the caster roll and defines a plurality of discreet pathways, which places the open ends of the longitudinally extending bores in fluid communication with one another. The end caps additionally define a pathway formed to place the open end of one bore in fluid communication with a coolant inlet or coolant outlet passageway of the caster roll. A similar cooling roll having longitudinally extending cooling channels is disclosed in published International Application No. PCT/EP01/09818 (WO 02/26425).
U.S. Pat. No. 5,209,283 to Miltzow et al. discloses a caster roll comprising a roll core with a plurality of threads and a threaded sleeve, which threads onto the threaded roll core. The threaded connection between the roll core and roll sleeve defines a spiral channel through which a cooling medium flows to cool the caster roll. A similar “threaded” roll core is disclosed in U.S. Pat. No. 5,292,298 to Scannell.
U.S. Pat. No. 4,944,342 to Lauener discloses a continuous caster roll for casting aluminum sheet material. The caster roll is comprised of a roll shell enclosing a roll core. Cooling medium flows through axial cooling channels defined in the outer surface of the roll core. A counter flow principle is applied in the caster roll in which the cooling medium alternately flows in the cooling channels from one end of the caster roll to the other.
Further, U.S. Pat. No. 4,773,468 also to Lauener, discloses a method for extending the service life of a caster roll. In the caster roll disclosed by the Launer '468 patent, a plurality of rods is placed axially in grooves formed in the roll core of the caster roll. The rods protrude radially outward from the roll core and a roll shell is shrink-fitted onto the rods. As the roll is used in production runs, the roll shell wears and once the wear has proceeded to a predefined lower limit, the rods are replaced and a new roll shell is shrink-fitted onto the rods. Other references in the field of internally cooled caster rolls include U.S. Pat. No.: 5,887,644 to Akiyoshi et al.; U.S. Pat. Nos. 2,850,776; 2,790,216; and 2,664,607 all to Hunter. The disclosure of each of the references identified hereinabove is incorporated into this disclosure by reference.
The foregoing references disclose various prior art arrangements and methods for manufacturing, internally cooling, and generally extending the service of caster rolls. Nonetheless, a need still exists for a reduced cost, internally cooled caster roll having an extended service life between roll shell replacements. Additionally, a need exists for a roll shell replacement method that reduces the costs associated with roll shell replacements generally, which is the primary capital outlay required to extend the service life of caster rolls.
The present invention is a caster roll used in the manufacturing of metal plate, strip, sheet, or foil. In one embodiment, the caster roll comprises a cylindrical roll core and at least one metal overlay formed on the roll core. The roll core has a central longitudinal axis and defines a plurality of longitudinally extending cooling passages for conducting a cooling medium through the roll core to cool the roll during use. The cooling passages may be located proximate to the surface of the roll core and may be spaced regularly about the central longitudinal axis of the roll core. The roll core may comprise a cylindrical roll body and two outward extending axles. The at least one metal overlay may be formed on the roll body. The cooling passages may extend substantially the entire length of the roll body, and may be spaced regularly about the central axis of the roll body.
The roll core may comprise at least one centrally located inlet passage and a plurality of radially extending passages extending from the at least one inlet passage to the cooling passages for conducting the cooling medium from the at least one inlet passage to the cooling passages. The at least one inlet passage may extend substantially parallel to the central longitudinal axis of the roll core and the radial passages may extend substantially perpendicular to the at least one inlet passage. Alternatively, the radial passages may each define an acute angle with the central longitudinal axis.
The roll core may further comprise at least one centrally located inlet passage and one centrally located outlet passage and a first and second plurality of radially extending passages. The first plurality of radially extending passages may extend from the at least one inlet passage to the cooling passages for conducting the cooling medium to the cooling passages and the second plurality of radially extending passages may extend from the cooling passages to the at least one outlet passage for conducting the cooling medium from the cooling passages to the at least one outlet passage. The at least one inlet passage and at least one outlet passage may extend substantially parallel to the central longitudinal axis of the roll core and the first and second plurality of radial passages may extend substantially perpendicular to the at least one inlet passage and at least one outlet passage. Alternatively, the first and second plurality of radial passages may each define an acute angle with the central longitudinal axis.
The at least one inlet passage and at least one outlet passage may extend from one of the axles of the roll core, through the roll body, and at least partially through the second axle. The cooling passages may extend the entire length of the roll body and end caps may be attached, respectively, to opposite ends of the roll body for closing the ends of the cooling passages.
In another embodiment, the roll generally comprises a cylindrical roll core having a central longitudinal axis and a metal overlay formed on the roll core. The metal overlay defines a plurality of cooling passages for conducting a cooling medium through the metal overlay to cool the roll during use. The cooling passages may extend substantially parallel to the central longitudinal axis of the roll core and longitudinally in the metal overlay, preferably substantially the entire length of the metal overlay. The cooling passages may be spaced regularly about the central longitudinal axis of the roll core.
The roll core may comprise a cylindrical roll body and two outward extending axles and the metal overlay may be formed on the roll body. The cooling passages may extend substantially the entire length of the roll body in the metal overlay. End caps may be attached, respectively, to opposite ends of the roll body for closing the ends of the cooling passages in the metal overlay.
In still another embodiment, the roll is generally comprised of a cylindrical roll core having a central longitudinal axis, a first metal overlay formed on the roll core, and at least one additional metal overlay formed on the first metal overlay. The first metal overlay preferably defines a plurality of cooling passages for conducting a cooling medium through the first metal overlay to cool the roll during use. Preferably, the first metal overlay has a hardness lower than the hardness of the at least one additional metal overlay. The cooling passages may extend substantially parallel to the central longitudinal axis of the roll core and substantially the entire length of the first metal overlay. The cooling passages may be spaced regularly about the central longitudinal axis of the roll core.
The roll may comprise a cylindrical roll body and two outward extending axles. The first metal overlay and the at least one additional metal overlay may be formed on the roll body. The cooling passages may extend substantially the entire length of the roll body and be spaced regularly about the central longitudinal axis of the roll core. End caps may be attached, respectively, to opposite ends of the roll body for closing the ends of the cooling passages in the first metal overlay.
The first metal overlay and the at least one additional metal overlay may each be formed to a thickness of less than about 6 inches and, preferably, between about 0.010 to 6 inches. The first metal overlay may be a thermally conductive metal, such as copper, bronze, steel, and the like. The at least one additional metal overlay may be a metal alloy, such as a nickel, cobalt, copper, or titanium based alloy. The at least one additional metal overlay may also be steel. The at least one additional metal overlay may be a single metal overlay formed on the first metal overlay and be comprised of any of the metals identified hereinabove.
The present invention is also a method of manufacturing a roll adapted for use in manufacturing metal plate, strip, sheet, or foil. The method may generally include the steps of: providing a cylindrical roll core having a central longitudinal axis; forming a plurality of longitudinally extending cooling passages in the roll core proximate to the surface of the roll core for conducting a cooling medium through the roll core to cool the roll during use; and forming at least one metal overlay on the roll core. The at least one metal overlay may be formed on the roll core by any one of the following processes or like processes: submerged arc welding, spray forming, thermal spraying, hot isostatic pressing, pack diffusion, vapor deposition, and electrolytic plating.
The cooling passages may be formed to be spaced regularly about the central longitudinal axis of the roll core. The step of forming the longitudinally extending cooling passages may comprise drilling holes in the roll core extending substantially parallel to the central longitudinal axis of the roll core. The roll core may have a roll body. The step of forming the longitudinally extending cooling passages may comprise drilling holes in the roll body extending substantially parallel to the central longitudinal axis of the roll core and the entire length of the roll body. The method may comprise the additional step of attaching end caps to opposite ends of the roll body to close the ends of the cooling passages. The method may further comprise the step of heat treating the roll to a temperature of between about 400° F. to 1500° F. for between about 1 to 48 hours after forming the at least one metal overlay on the roll core, particularly when the at least one metal overlay comprises steel.
The roll core may define at least one centrally located and longitudinally extending inlet passage. The method may further comprise the steps of: forming a plurality of radially extending passages in the roll core to connect the cooling passages to the at least one inlet passage; and plugging the radial passages at the surface of the roll core prior to the step of forming the at least one metal overlay on the roll core. The step of forming the radially extending cooling passages in the roll core may comprise drilling holes in the roll core extending substantially perpendicular to the central longitudinal axis of the roll core to connect the cooling passages to the at least one inlet passage. Alternatively, the step of forming the radially extending cooling passages in the roll core may comprise drilling holes in the roll core at an acute angle with respect to the central longitudinal axis of the roll core to connect the cooling passages to the at least one inlet passage.
The roll core may further define at least one centrally located and longitudinally extending outlet passage. The method may further comprise the steps of: forming a plurality. of radially extending passages in the roll core to connect the cooling passages to the at least one inlet passage and the at least one outlet passage; and plugging the radial passages at the, surface of the roll core prior to the step of forming the at least one metal overlay on the roll core. The radially extending cooling passages may be drilled in the roll core to extend substantially perpendicular to the central longitudinal axis of the roll core or at an acute angle with respect to the central longitudinal axis of the roll core to connect the cooling passages to the at least one inlet passage and at least one outlet passage.
In another embodiment, the method of manufacturing the roll generally comprises the steps of: providing a cylindrical roll core having a central longitudinal axis; forming a metal overlay on the roll core; and forming a plurality of longitudinally extending cooling passages in the metal overlay for conducting a cooling medium through the metal overlay to cool the roll during use. The metal overlay may be formed on the roll core by any of the processes indicated previously.
The cooling passages may be formed in the metal overlay to be spaced regularly about the central longitudinal axis of the roll core. The step of forming the longitudinally extending cooling passages may comprise drilling holes in the metal overlay extending substantially parallel to the central longitudinal axis of the roll core. The holes may be drilled in the metal overlay to extend substantially the entire length of the roll body. End caps may be attached to opposite ends of the roll body to close the ends of the cooling passages in the metal overlay. The roll may be heat treated to a temperature of between about 400° F. to 1500° F. for between about 1 to 48 hours after forming the metal overlay on the roll core, particularly when the metal overlay comprises steel.
The roll core may define at least one centrally located and longitudinally extending inlet passage. The method may further comprise the steps of: forming a plurality of radially extending passages in the metal overlay and roll core to connect the cooling passages to the at least one inlet passage; and plugging the radial passages at the surface of the metal overlay. The step of forming the radially extending cooling passages in the roll core may comprise drilling holes in the metal overlay and roll core extending substantially perpendicular to the central longitudinal axis of the roll core or at an acute angle with respect to the central longitudinal axis to connect the cooling passages to the at least one inlet passage.
The roll core may further define at least one centrally located and longitudinally extending outlet passage, and the method may further comprise the steps of: forming a plurality of radially extending passages in the metal overlay and roll core to connect the cooling passages to the at least one inlet passage and the at least one outlet passage; and plugging the radial passages at the surface of the metal overlay.
In another embodiment of the method of manufacturing the roll of the present invention, the method generally includes the steps of: providing a cylindrical roll core having a central longitudinal axis; forming a first metal overlay on the roll core; forming a plurality of longitudinally extending cooling passages in the first metal overlay for conducting a cooling medium through the first metal overlay to cool the roll during use; and forming at least one additional metal overlay on the first metal overlay. The first metal overlay and the at least one additional metal overlay may be formed on the roll core by any of the processes indicated previously. The cooling passages are preferably formed in the first metal overlay to be spaced regularly about the central longitudinal axis of the roll core. The step of forming the longitudinally extending cooling passages may comprise drilling holes in the first metal overlay extending substantially parallel to the central longitudinal axis of the roll core. End caps may be attached, respectively, to opposite ends of the roll body to close the ends of the cooling passages in the first metal overlay. The roll may be heat treated to a temperature of between about 400° F. to 1500° F. for between about 1 to 48 hours after forming the at least one additional metal overlay on the first metal overlay, particularly when the first metal overlay and/or the at least one additional metal overlay comprises steel.
The roll core may define at least one centrally located and longitudinally extending inlet passage and at least one centrally located and longitudinally extending outlet passages. The method may further comprise the steps of: forming a plurality of radially extending passages in the first metal overlay and roll core to connect the cooling passages to the at least one inlet passage; and plugging the radial passages at the surface of the first metal overlay prior to the step of forming the at least one additional metal overlay on the first metal overlay. The step of forming the radially extending cooling passages in the roll core may comprises drilling holes in the first metal overlay and roll core extending substantially perpendicular to the central longitudinal axis of the roll core or at an acute angle with respect to the central longitudinal axis of the roll core to connect the cooling passages to the at least one inlet passage.
The method also comprises the steps of: forming a plurality of radially extending outlet passages in the first metal overlay and roll core to connect the cooling passages to the at least one inlet passage and the at least one outlet passage; and plugging the radial passages at the surface of the first metal overlay prior to the step of forming the at least one additional metal overlay on the first metal overlay. The step of forming the radially extending cooling passages in the roll core may comprise drilling holes in the first metal overlay and roll core extending substantially perpendicular to the central longitudinal axis of the roll core or at an acute angle with respect to the central longitudinal axis of the roll core to connect the cooling passages to the at least one inlet passage and at least one outlet passage.
Additionally, the method of the present invention relates to resurfacing existing rolls, which may be adapted for use in manufacturing metal plate, strip, sheet, or foil. The resurfacing method generally comprises the steps of: providing an existing roll having a central longitudinal axis and a roll core comprising a work surface defining grooves or channels; removing the existing work surface from the roll core to form a substantially smooth surface; forming a first metal overlay on the substantially smooth surface of the roll core; forming a plurality of longitudinally extending cooling passages in the first metal overlay; and forming at least one additional metal overlay on the first metal overlay.
The resurfacing method may further comprise the step of connecting the cooling passages to existing cooling conduits in the roll core. The first metal overlay and the at least one additional metal overlay may be formed on the roll core by any of the processes indicated previously.
Further details and advantages of the present invention will become apparent from the following detailed description when read in conjunction with the drawings, wherein like parts are designated with like reference numerals throughout.
Referring to
The roll core 12 has a generally cylindrical construction and comprises a cylindrical center section or roll body 18 and two outward extending axles 20, 22. The first and second metal overlays 14, 16 are formed on top of the roll body 18, as discussed hereinafter. The roll body 18 forms the portion of the caster roll 10 that contacts or casts metal when the caster roll 10 is used in connection with continuous sheet casting machines (not shown). The caster roll 10 is intended for use with metal that may be in solid, semi-solid, or liquid form. One of the axles 20, 22 is preferably configured to be driven by the casting machine. Either axle 20, 22 may be configured as the “drive end” axle of the caster roll 10. For convenience in explaining the present invention, axle “20” will be referred to hereinafter as the “drive end axle 20” or “first axle 20”. The other axle 22 is configured to admit a cooling medium into the roll core 12 and discharge the same in the manner discussed hereinafter and will be referred to as the “cooling end axle 22” or “second axle 22”. A preferred cooling medium for the caster roll 10 is water. Cooling mediums other than water, such as oil or glycol, may be used in the caster roll 10, however water is preferred. The cooling medium may be a mixture of cooling mediums and chemical additives added to the cooling medium for preventing corrosion. The roll core 12 may be formed of 4340 Steel (i.e., low carbon steel) and substantially equivalent metals and materials. The cooling medium is referred to as cooling water hereinafter, but any of the cooling mediums (and mixtures) set forth hereinabove may be used in place of “cooling water” in the following discussion.
The roll core 12 defines one or more centrally located passages 24 that extend substantially through the roll core 12. The central passages 24 may also extend entirely through the roll core 12. In the caster roll 10 shown in
As indicated, the central passages 24 provide inlet (i.e., supply) and outlet (i.e., return) conduits for carrying water into and out of the roll core 12. In particular, the central passages 24 are generally divided into two cooling water inlet passages 26 and two cooling water outlet passages 28. The inlet and outlet passages 26, 28 are interconnected, respectively, and form two separate cooling water flow circuits in the roll core 12, which are identified herein with additional reference characters “a” and “b” for clarity. Accordingly, one of the inlet passages 26a is connected to one of the outlet passages 28a to form a first flow circuit, and the second inlet passage 26b is connected to the second outlet passage 28b to form a second flow circuit within the roll core 12. The cooling water “flow circuits” to be described hereinafter are an exemplary arrangement for cooling the roll core 12 and caster roll 10 of the present invention and may be replaced by any equivalent fluid flow arrangement, which is within the skill of one skilled in the art.
The openings to the inlet passages 26a, 26b and outlet passages 28a, 28b are located at the cooling end axle or second axle 22. The inlet passages 26a, 26b and outlet passages 28a, 28b preferably extend from the cooling end axle 22 through the roll body 18 and partially through the drive end axle 20. The inlet passages 26a, 26b and outlet passages 28a, 28b are preferably connected together, respectively, in both the drive end axle 20 and the cooling end axle 22. Alternatively, the inlet passages 26a, 26b and outlet passages 28a, 28b may be connected together, respectively, in either the drive end axle 20 or the cooling end axle 22. The inlet passages 26a, 26b carry cooling water from the cooling end axle 22 through the roll body 18 and into the drive end axle 20, and the outlet passages 28a, 28b then return the now heated water back to the cooling end axle 22, as described further herein.
The roll body 18 of the roll core 12 further defines a plurality of radially extending passages 30 that extend outward from the inlet passages 26a, 26b and outlet passages 28a, 28b to a surface 31 of the roll body 18. The radial passages 30 are generally in fluid communication with passages formed in the first metal overlay 14, as discussed herein. The inlet passages 26a, 26b are each preferably connected to four (4) radial passages 30, and the outlet passages 28a, 28b are each preferably connected to four (4) radial passages 30. However, additional or fewer radial passages 30 may be connected to the inlet passages 26a, 26b and outlet passages 28a, 28b. The choice of four (4) radial passages 30 connected to the inlet passages 26a, 26b and four (4) radial passages 30 connected to the outlet passages 28a, 28b is provided as an example to describe the caster roll 10. At a minimum, only one (1) radial passage 30 is required for each of the inlet passages 26a, 26b and outlet passages 28a, 28b. In the preferred embodiment, the radial passages 30 are formed into the roll body 18 after the first metal overlay 14 is applied to the roll body 18, as discussed hereinafter. Alternatively, the radial passages 30 may be formed in the roll body 18 prior to forming the first metal overlay 16.
The radial passages 30 are preferably symmetrically distributed around the circumference of the roll body 18 and in fluid communication with longitudinal passages that may be formed in the first metal overlay 14, as discussed further hereinafter. The radial passages 30 defined in the roll body 18 of the roll core 12 are provided to conduct cooling water to these “longitudinal passages” and then return heated water to the central passages 24. In general, cooling water is conducted through inlet passages 26a, 26b, outward in the roll body 18 through the radial passages 30. Heated water is returned through the radial passages 30 to the outlet passages 28a, 28b. The outlet passages 28a, 28b then conduct the heated water out of the roll core 12. The radial passages 30 are preferably provided at both ends of the roll body 18 (i.e., proximate to the ends of the roll body 18), but may also be located at only one end of the roll body 18.
The inlet passages 26a, 26b conduct cooling water into the roll core 12 and, for this purpose, are preferably in fluid communication with an external source of cooling water (not shown) such as an evaporative cooling system (i.e., cooling tower). The outlet passages 28a, 28b return heated water to the cooling water source, or other location. The radial passages 30 enable cooling water to be conducted from the inlet passages 26a, 26b to the first metal overlay 14 and returned to the outlet passages 28a, 28b.
Referring to
The caster roll 10 according the present invention is provided with a plurality of enclosed cooling medium conduits or passages 34 that extend longitudinally in the caster roll 10 for cooling the caster roll 10 during use. In the presently preferred embodiment of the caster roll 10, the cooling passages 34 are formed in the first metal overlay 14. In another embodiment of the caster roll 10, the cooling passages 34 are formed in the roll core 12. The cooling passages 34 are placed in fluid communication with the inlet passages 26a, 26b and outlet passages 28a, 28b preferably by forming (i.e., drilling) the radial passages 30 into the roll core 12 after the first metal overlay 14 is formed on the roll core 12 and the cooling passages 34 are formed (i.e., by drilling longitudinally) in the first metal overlay 14. The embodiment of the caster roll 10 wherein the cooling passages 34 are provided in the first metal overlay 14 will be discussed next in this disclosure. The embodiment of the caster roll 10 wherein the cooling passages 34 are provided in the roll core 12 is discussed in connection with
The cooling passages 34 preferably extend substantially parallel to a central longitudinal axis L of the roll core 12 and radially outward from the central longitudinal axis L. The cooling passages 34 further preferably extend the entire length of the first metal overlay 14 and the roll body 18 and are spaced regularly about the circumference of the roll body 18. As indicated previously, the cooling passages 34 may be formed by drilling longitudinal holes the length of the first metal overlay 14. Additionally, as indicated previously, the radial conduits 30 may be formed by drilling radially into the first metal overlay 14 and roll core 12 to connect the cooling passages 34 to the central passages 24 (i.e., the inlet passages 26a, 26b and outlet passages 28a, 28b). In practice, the cooling passages 34 are only required to extend substantially the distance between the openings of the radial passages 30 to connect the cooling passages 34 to the inlet passages 26a, 26b and outlet passages 28a, 28b. Consequently, the cooling passages 34 are not necessarily limited to extending the entire length of the first metal overlay 14.
The first metal overlay 14 is preferably made of a metal or metal alloy exhibiting good thermal conductivity properties such as copper, bronze, steel, stainless steel, and the like. The second metal overlay 16 is preferably a metal that is resistant to thermal fatigue cracking wear. A suitable metal for the second metal overlay 16 will have a hardness range in the range of 30 to 66 Rockwell C, preferably 55 to 60 Rockwell C. An exemplary list of metals for the second metal overlay 16 includes: steel and nickel, cobalt, copper, and titanium based alloys.
The cooling passages 34 are preferably formed so that adjacent pairs of cooling passages 34 are interconnected at one of the ends of the roll body 18 of the roll core 12. Thus, the adjacent pairs of cooling passages 34 form cooling flow paths or conduits comprised of one “inlet” or “supply” cooling passage 34, which is connected to a radial passage 30 that is in turn connected to one of the inlet passages 26a, 26b, and one “outlet” or “return” cooling passage 34, which is connected to a radial passage 30 that is in turn connected to one of the outlet passages 28a, 28b. Accordingly, the cooling passages 34, radial passages 30, and inlet and outlet passages 26, 28 are all in fluid communication and define an internal cooling medium flow system within the caster roll 10 that distributes cooling water from an external source to the interior of the roll core 12 and roll body 18 through the inlet passages 26a, 26b, then outward in the roll body 18 through the radial passages 30, and finally to the interior of the first metal overlay 14 through the cooling passages 34. An analogous return path to the external source of cooling water is also provided by the above-described flow system, as will be appreciated by one skilled in the art. The cooling passages 34 are not required to be interconnected, and may be provided as single cooling passages 34.
As indicated previously, an additional metal overlay such as the second metal overlay 16 and, possibly, multiple metal overlays or coatings may be formed on top of the first metal overlay 14. The second metal overlay 16 is formed on the surface 32 of the first metal overlay 14 preferably by any one of the metal deposition processes or techniques identified previously. For example, the second metal overlay 16 may be provided as a thin, hard coating of metal such as tungsten, carbide, or chromium, which is applied to the surface 32 of the first metal overlay 14 by a vapor deposition technique, an electrolytic plating technique (i.e., for chromium), or by one of the techniques identified previously.
End caps 36 (also shown in
With continued reference to
Once the first metal overlay 14 is formed on the surface 31 of the roll body 18, the cooling passages 34 may be formed in the first metal overlay 14. This is accomplished by drilling longitudinally extending holes in the first metal overlay 14, which form the cooling passages 34. The cooling passages 34 are preferably formed at regular angular intervals around the roll body 18. The cooling passages 34 are spaced radially outward from the central passages 24 (i.e., inlet and outlet passages 26, 28) and the central longitudinal axis L.
Once the longitudinally extending cooling passages 34 are formed in the first metal overlay 14, the cooling passages 34 may be formed in the roll core 12 to place the cooling passages 34 in fluid communication with the central passages 24 (i.e., inlet and outlet passages 26, 28) in the roll core 12. The cooling passages 34 are formed by drilling radially into the first metal overlay 14 and roll core 12 at the desired pre-selected angular locations where the radial passages 30 are to be located in the roll core 12. The drilling process forms radial holes 44 in the first metal overlay 14 that must be plugged before the second metal overlay 16 is formed on the first metal overlay 14. The radial holes 44 are plugged by a plurality of plugs 46, as shown in
As discussed previously, any number of longitudinally extending cooling passages 34 may be provided in the first metal overlay 14, which may be placed in fluid communication with any number of radial passages 30 formed in the roll core 12. The cooling passages 34 are intended to conduct cooling water through the first metal overlay 14, preferably the length of the first metal overlay 14, and return heated water to the radial passages 30 in fluid communication with the outlet passages 28a, 28b.
Once the longitudinally extending cooling passages 34 and radial passages 30 are formed in the first metal overlay 14 and roll body 18 of the roll core 12, the second metal overlay 16 is preferably formed directly on top of the first metal overlay 14. The second metal overlay 16 may be applied by any of the metal deposition or forming processes indicated previously. The second metal overlay 16 is preferably made of any of the hard metals identified previously. The second metal overlay 16 will generally have a hardness higher than the hardness of the first metal overlay 14. Preferably, the first and second metal overlays 14, 16 each have a thickness of about 0.010 to 6 inches. The second metal overlay 16 generally forms the “work surface” of the caster roll 10.
The caster roll 10 may be subjected to further treatment steps once the second metal overlay 16 is formed on the first metal overlay 14. For example, the caster roll 10 may be heat treated to a temperature of between about 400° F. to about 1500° F. for a time period of about 1 to 48 hours to produce a hardness in the range of about 30 to 66 Rockwell C, as indicated previously, in the first and second metal overlays 14, 16, particularly when the first and second metal overlays 14, 16 comprise steel. Additionally, a surface 50 of the second metal overlay 16 (i.e., the preferred work surface of the caster roll 10) may be roughened such that the surface 50 of the second metal overlay 16 has a surface roughness suitable for manufacturing commercial aluminum plate, strip, sheet, or foil. The plugs 46 are preferably formed flush with the surface 32 of the first metal overlay 14, or recessed into the first metal overlay 14 before the second metal overlay 16 is formed on the first metal overlay 14. The deposition or formation of the second metal overlay 16 onto the first metal overlay 14 will fill any recesses defined in the first metal overlay 14 in the vicinity of the plugs 46.
In an alternative embodiment of the caster roll 10, the second metal overlay 16 may be omitted from the caster roll 10, such as illustrated in FIG. 11. The surface 32 of the first metal overlay 14 will now form the “work surface” of the caster roll 10. Accordingly, the first metal overlay 14 in this embodiment is preferably formed of a hard metal, such as the metals identified previously in connection with the second metal overlay 16. The metal plugs 46 are used to seal the radial holes 44 formed in the first metal overlay 14. The plugs 46 are preferably formed flush with the surface 32 of the first metal overlay 14. The true “work surface” area for this alternative embodiment of the caster roll 10 is generally the surface 32 of the first metal overlay 14 lying between the plugs 46. The previously discussed heat treatment and surface roughening steps may be also be applied to the caster roll 10 having only the first metal overlay 14 as the “work surface” of the caster roll 10.
Additionally, as shown in dotted lines in
The methods described hereinabove for applying the first and second metal overlays 14, 16, as well. as additional metal overlays (if any), to the roll body 12 may also be applied to existing caster rolls. Specifically, the first and second metal overlays 14, 16 may be applied to, for example, existing caster rolls having circumferential grooves or channels that define water passages for cooling the caster roll. A typical example of such a “grooved” or “channeled” caster roll is disclosed in U.S. Pat. No. 5,292,298 to Scannell, discussed previously.
The first and second metal overlays 14, 16 may be applied, for example, to the caster roll disclosed by the Scannell patent by removing the roll shell from the roll core and, further, the machined circumferential grooves or channels (i.e., spiral ribs) formed on the roll core. The resulting roll core preferably has a substantially smooth surface, which generally means that the roll core is free of the original machined grooves or channels (i.e., spiral ribs). The first metal overlay 14 may then be applied as described previously. The longitudinally extending cooling passages 34 may be formed in the first metal overlay 14 in the manner discussed previously. Thereafter, the cooling passages 34 may be placed in fluid communication with existing radial and axial bores, channels, or conduits defined in the roll core of the existing caster roll, such as the heat transfer roll disclosed by the Scannell patent. The plugs 46 may be used to seal the radial holes 44 formed in the first metal overlay 14. Finally, the second metal overlay 16 and possibly additional metal overlays may be formed on the first metal overlay 14 in the manner described previously. The process described previously for forming the caster roll 10 having only one metal overlay (i.e., the first metal overlay 14) may also be used to “resurface” the existing caster roll, such as the heat transfer roll disclosed by the Scannell patent. The disclosure of the Scannell patent is relied upon only to illustrate the application of the processes discussed previously for forming the caster roll 10 of the present invention to existing caster rolls. The foregoing “retro-fitting” or “resurfacing” process is believed to be applicable to any internally cooled caster roll used in the continuous sheet casting field and this disclosure should not be interpreted as being applicable only to the specific arrangement of the caster roll disclosed by the Scannell patent.
Referring to
In general, the embodiment of the caster roll 10 shown in
The flow pattern of the cooling water within the caster roll 10 and associated method of cooling the caster roll 10 will generally be described hereinafter with reference to
The radial passages 30 and cooling passages 34 are preferably arranged to provide a plurality of counter-flowing cooling water circuits in the first metal overlay 14 (or roll body 18). Referring, in particular, to
As described previously, the cooling passages 34 are preferably arranged in pairs, with each pair including an “inlet” cooling passage 34 and an interconnected “outlet” cooling passage 34 that returns heated water to one of the radial passages 30 for removal from the caster roll 10. Thus, the supply radial passages 30 at the first end 38 of the roll body 18 supply cooling water to respective inlet cooling passages 34 that carry cooling water from the first end 38 to the second end 40 of the roll body 18 of the roll core 12. Heated water is returned to the starting point (first end 38) through the respectively interconnected outlet cooling passages 34. Similarly, the supply radial passages 30 at the second end 40 of the roll body 18 supply cooling water to respective inlet cooling passages 34 that carry cooling water from the second end 40 of the roll body 18 to the first end 38 (i.e., in the opposite direction). Again, heated water is returned the length of the first metal overlay 14 (or roll body 18) through the respectively interconnected outlet cooling passages 34. Heated water is conducted away from the first metal overlay 14 through the return radial passages 30 provided at both ends 38, 40 of the roll body 18. The return radial passages 30 are in fluid communication with the outlet passages 28a, 28b, which conduct the heated water from the caster roll 10. As will be appreciated by those skilled in the art, the first metal overlay 14 and second metal overlay 16 formed thereon are cooled by counter-flowing cooling water flows, which flow the length of the first metal overlay 14 (or roll body 18).
The casting roll 10 and procedures for making the same described hereinabove result in a caster roll having reduced maintenance and repair costs. Additionally, the deposition of the first and second metal overlays 14, 16, for example by submerged arc welding, on the roll core 12 eliminates the roll shell/roll core slippage problem that is well known in the art. Further, the use of multiple metal overlays on the roll core 12 reduces the possibility of cooling water leaking onto the external surface of the caster roll 10 (i.e., surface 50), which improves the safety of the caster roll 10 when in use. It is believed that the roll shell replacement costs associated with prior art caster rolls may be reduced significantly using the processes described hereinabove and that the eccentricity problem associated with prior art caster roll may be reduced by up to about half (i.e., 50%).
While preferred embodiments of the present invention were described hereinabove, obvious modifications and alterations of the present invention may be made without departing from the spirit and scope of the present invention. The scope of the present invention is defined in the appended claims and equivalents thereto.
This application claims the benefit of U.S. Provisional Patent Application Ser. No. 60/438,721, filed Jan. 8, 2003, entitled “Caster Roll and Method of Manufacture”.
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Number | Date | Country |
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WO 0226425 | Apr 2002 | WO |
Number | Date | Country | |
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20040129403 A1 | Jul 2004 | US |
Number | Date | Country | |
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60438721 | Jan 2003 | US |