Background of the Invention
1. Field of the Invention
[0001] The invention relates to a chill casting wheel for the continuous casting of filamentary
material. More particularly, the invention relates to casting wheels used to cast
glassy metal filaments.
2. Description of the Prior Art
[0002] In the production of glassy alloy continuous filaments, typically an appropriate
molten alloy is quenched at extreme quench rates, usually at least about 10
4°C per second by extruding the molten alloy from a pressurized reservoir through an
extrusion nozzle onto a high speed rotating quench surface as is representatively
shown in U.S. Patent 4,142,571 for "Continuous Casting Method for Metallic Strips"
issued March 6, 1978 to Narasimhan, hereby incorporated by reference. Such filaments
are necessarily thin, typically about 25-100 microns, due to the extreme heat transfer
rate required to prevent substantial crystallization, though considerable selectivity
may be exercised respecting the transdimensions and cross-section of the filament.
[0003] U.S. Patent No. 4,307,771 for "Force-Convection-Cooled Casting Wheel" issued December
29, 1981 to S. Draizen, et al. shows a casting wheel having a thick stiffening section
which supports the quench surface and contains peripheral, drilled coolant passages
located in proximity to the quench surface. The wheel is constructed to resist crowning-type
distortions where the casting wheel radius at the quench surface edges becomes less
than the wheel radius at the quench surface circumferential center line. When casting
wide filaments greater than about 5 cm in width, however, such stiffened casting wheels
do not provide sufficient crowning resistance.
[0004] Contoured quench surfaces have been used to address the crowning problem on rollers.
However, casting wheels with contoured quench surfaces have been unsatisfactory because
each particular contoured surface is effective only when specific use conditions of
temperature and filament width are met. A variation in filament width, extrusion temperature
or filament quench rate prevents the contoured surface from properly compensating
for crowning-type distortions. Other problems with contoured quench surfaces include
the cost and difficulty of initially machining the complex contours on the casting
wheel quench surface and of periodically refurbishing the quench surface to maintain
the precise contour.
[0005] Thus, ordinary casting wheels remain susceptible to crowning-type distortion problems,
especially when wider filaments are cast. The wheels are difficult to refurbish and
are unable to satisfactorily cast filaments having varied widths or requiring varied
quench rates.
Summary of the Invention
[0006] The invention provides a chilled casting wheel that resists crowning, affords uniform
quenching of wide ribbon and is economical to manufacture and refurbish. Generally
stated, the casting wheel includes an annular wheel core member which has axially
extending channels formed about a circumferential, outer peripheral surface thereof
and is adapted to rotate about a concentric axis of rotation. A cylindrical axially
extending wheel rim member is concentrically connected to the core peripheral surface
and has a preselected interference fit therewith to provide a preselected residual,
circumferential tensile stress within the rim. A coolant means directs a fluid coolant
to the interior surface of the rim and through the channels of the wheel core.
[0007] In a preferred embodiment, the casting wheel of the invention includes a hub shaft
member which has a concentric axis of rotation and two axial end portions. Each end
portion delimits an axial coolant chamber having at least one, but preferably a plurality
of coolant supply passages communicating radially therefrom. An annular wheel core
member is concentrically connected to the hub shaft and adapted to rotate therewith.
The wheel core has axially extending coolant channels formed about an outer peripheral
surface thereof and two axially facing side portions. A cylindrical, axially extending
wheel rim member is concentrically connected to the peripheral core surface and has
a preselected interference fit therewith to provide a residual, circumferential tensile
stress within the rim. Two annular flange members are connected concentric with the
hub shaft and adjacent to each of the core side portions to delimit an annular coolant
chamber at each side of the wheel core which communicates with its respective coolant
supply passages.
[0008] The casting wheel of the invention is over eight times more resistant to crowning
than ordinary casting wheels, and is able to cast filament of greater width having
more uniform dimensions and physical properties. The casting wheel provides improved
heat transfer and more uniform quenching across the width of the wheel, and since
the more rigid casting wheel construction has less tendency to become eccentric when
rotating and subjected to thermal loads, the wheel is able to cast any width ribbon,
less than the width of the wheel, at random locations across the quench surface without
crowning problems. In addition, the wheel is easier to refurbish because the casting
wheel rim can be easily replaced whenever it becomes worn or damaged. Since the wheel
core and other parts are reusable, costs are greatly reduced. With the two piece construction,
different, individually suited materials can be used for the wheel core and the wheel
rim as required. Thus, the invention provides a less expensive and more versatile
casting wheel that is more resistant to crowning, provides improved quenching, is
easier to maintain and refurbish and is capable of casting wider filaments than ordinary
casting wheels having thickened support sections or contoured quench surfaces.
Brief Description of the Drawings
[0009] The invention will be more fully understood and further advantages will become apparent
when reference is made to the following detailed description of the preferred embodiment
of the invention and the accompanying drawings in which:
FIG. 1 is a simplified perspective view of an apparatus for continuous casting of
metallic strip;
FIG. 2 is a partial cross-sectional view of the casting wheel of the invention;
FIG. 3 is a fractional cross-sectional view taken along line A-A of Fig. 1; and
FIG. 4 is a schematic representation of casting wheel surface crowning.
Description of the Preferred Embodiments
[0010] For the purposes of this invention and as used in the specification and claims, theterm
"filament" is a slender body whose transverse dimensions are much smaller than its
length. Thus, the term filament includes wire, ribbon, sheet and the like of regular
or irregular cross-section.
[0011] Referring to Fig. 1 of the drawings, a representative apparatus for the continuous
casting of a glassy alloy filament is illustrated to point out the general use of
the present invention. An extrusion means is comprised of a reservoir crucible 24
and an extrusion nozzle 26. Molten alloy contained in crucible 24 is heated by a heating
element 25, and pressurization of the crucible with an inert gas extrudes a molten
stream through nozzle 26 located at the base of the crucible onto quench surface 23
of casting wheel 22.
[0012] The apparatus of this invention is suitable for forming polycrystalline strip of
aluminum, tin, copper, iron, steel, stainless steel and the like. However, metal alloys
that upon rapid cooling from the meltform solid amorphous, glassy structures are preferred.
Such alloys are well known to those skilled in the art, and examples are disclosed
in U.S. Patent Nos. 3,427,154; 3,981, 722 and others.
[0013] Fig. 2 shows the casting wheel of the invention generally at 22. An annular wheel
core member 7 has axially extending channels 8 formed about a circumferential, outer
peripheral surface 11 thereof and is adapted to rotate about a concentric axis of
rotation 28. A cylindrical, axially extending wheel rim member 10 is concentrically
connected to the core peripheral surface 11 and has a preselected interference fit
therewith to provide a preselected, residual, circumferential tensile stress within
the rim. A coolant means directs a fluid coolant to the interior surface 29 of rim
10 through channels 8.
[0014] Figs. 2 and 3 show a preferred embodiment of the casting wheel of the invention wherein
the coolant means is comprised generally of hub shaft member 1 and two flange members
12. In this embodiment, hub shaft member 1 has a concentric axis of rotation 28 and
two axial end portions 2. The end portions delimit axial coolant chambers 3 and 4,
and at least one, but preferably a plurality of coolant supply passages 5 and 6 communicate
radially from chambers 3 and 4, respectively. An annular wheel core member 7, concentrically
connected to hub shaft 1, is adapted to rotate therewith and provides two axially
facing side portions 9. A plurality of axially extending channels 8 are formed aboutthe
outer peripheral surface 11 of the core, and a cylindrical, axially extending wheel
rim 10 is mounted thereon. Rim 10 has a preselected interference fit with core 7to
provide a preselected residual, circumferential tensile stress within rim 10. Two
annularflange members 12 are connected concentric with hub shaft 1 and adjacentto
each of the core side portions 9 to delimit annular coolant chambers 13 and 14 at
each side of wheel core 7 which communicate with their respective coolant supply passages
5 and 6.
[0015] Hub shaft 1 is constructed of a suitable material, such as metal, and provides two
opposite end portions 2. An inlet chamber 3 is cast or machined into one end portion
and a plurality of outlet passages 5 are formed radially through hub shaft 1 to communicate
and conduct coolant from chamber 3. Similarly, an outlet chamber 4is cast or machined
into the opposite end portion, and a plurality of passages 6 communicate radially
from chamber 4.
[0016] Annular wheel core member 7 is constructed of a suitable material, such as stainless
steel, but preferably is constructed of a material having a low coefficient of thermal
expansion, such as INVAR (registered trademark), an iron-nickel alloy consisting essentially
of 64% iron and 36% nickel. Core 7 provides two axially facing side portions 9, and
is concentrically connected to hub shaft 1 by means of a conventional annular locking
assembly 15 to rotate with hub shaft 1. By constructing core 7 from INVAR alloy and
employing locking assembly 15, the casting wheel has improved dimensional stability,
less runout and a reduced tendency to expand or become eccentric during the filament
quenching operation. Axially extending channels 8 are formed about outer peripheral
surface 11 by a suitable method, such as machining. The machined channels are easier
and less expensive to produce than the drilled passages employed by conventional casting
wheels. Channels 8 allow a coolant flow across the width (measured axially) of core
7 which contacts the interior surface 29 of rim 10 and thereby cools quench surface
23. In the shown embodiment, channels 8 are spaced approximately 0.25 in (0.64 cm)
apart and configured to provide a desired volume of coolant flow.
[0017] Cylindrical, axially extending wheel rim 10 is concentrically connected to peripheral
core surface 11 with a preselected interference fit to provide a residual, circumferential
tensile stress within rim 10. A preferred material for rim 10 is a beryllium-copper
alloy because of its higher thermal conductivity. To obtain the desired interference
fit, rim 10 is shrink fitted onto wheel core 7. For example, when producing a 15 in.
diameter casting wheel, rim 10 is constructed with an inside radius approximately
30 mils (0.076 cm) smaller than the radius of peripheral surface 11. Rim 10 is then
heated to a temperature of approximately 600°F (316°C) to expand the radial dimension
of the rim and allow placement about surface 11 of core 7. Upon cooling, rim 10 contracts
to form an interference fit onto surface 11 which produces an internal residual tensile
stress within the rim of approximately 75,000 psi (517,107 KPA). It is readily apparent
that various amounts of interference fit are suitable, provided the resultant residual
stress is less than the yield stress of the rim material but large enough to hold
rim 10 in contact with core 7 against the thermal loads encountered during the casting
operation.
[0018] Two annular radially extending support rings 20 connect to core 7 by means of an
interference fit into a circumferential groove machined into each of the core side
portions 9. Rings 20 support the edges of rim 10 and provide a sealing surface against
which to connect the respective flange members 12. A plurality of openings 21 extend
through ring 20 to allow coolant to flow to annular, radially extending channels 30
and 33 machined into the peripheral edges of their respective core side portions.
Channels 30 and 33 are suitably sized and configured to conduct coolant between the
respective rings 20 and channels 8.
[0019] Two annular, dished flange members 12 are connected concentric with hub shaft 1 and
adjacent to each of the core side portions 9 to delimit an annular inlet coolant chamber
13 at one side of core 7 and an annular outlet coolant chamber 14 at the opposite
side of core 7. Coolant chamber 13 communicates with axial chamber 3 through passages
5, and coolant chamber 14 communicates with axial chamber 4 through passages 6. The
outer edge of each flange 12 mates against its respective edge of rim 10 and the corresponding
support ring 20, and is provided with a fluid seal, such as an elastomeric 0-ring
seal 31. The inner edge of each flange 12 mates with hub shaft 1 and is provided with
a fluid seal, such as an elastomeric 0-ring seal 32. A plurality of coolant vanes
16, connected to core 7 and disposed within chambers 13 and 14, direct coolant radially
through chambers 13 and 14.
[0020] Suitable bearings 17 are positioned about hub shaft 1 and are spaced from the sides
of flange members 12 by suitable spacers 18. Assembly nuts 19 are then threaded onto
hub shaft 1 and suitably torqued to provide compressive, axial loads of approximately
12,000 Ib - force (53,379 N) which hold flange members 12 in sealing engagement with
hub shaft 1, rim 10 and support rings 10. The end portions of hub shaft 1 are suitably
connected to a source of fluid coolant by means of conventional rotating unions.
[0021] During operation, a suitable fluid coolant, such as water, flows from a source into
axial chamber 3, then through passages 5 and into inlet chamber 13. Vanes 16 direct
coolant through openings 21 in support ring 20 and into channel 30, after which it
flows through channels 8 contacting rim 10 to cool quench surface 23. The coolant
then enters channel 33 and flows through openings 21 into outlet chamber 14. Vanes
16 direct the coolant to passages 6 through which it flows into axial chamber 4 and
then away from the wheel. Wheel 22 is spun up to a desired rotational speed and molten
metal is extruded from crucible 24 through nozzle 26 onto quench surface 23 to produce
continuous filament 27.
[0022] The residual circumferential tensile stress in rim 10 provides substantially improved
crowning resistance by counteracting the thermally induced stresses that tend to increase
the rim radius at the circumferential center line of the rim relative to the rim radius
at the edges of the rim. As representatively shown in Fig. 4, a thermal gradient,
between a hot quench surface 23 and a cool interior surface 29, induces a thermal
stress which tends to expand quench surface 23 relative to interior surface 29 and
thereby tends to bend (crown) rim 10. The residual tensile stress in rim 10, however,
counteracts this thermal stress to hold rim 10 substantially flat across the width
of core 7, thus providing a dimensionally stable quench surface 23 having marked resistance
to crowning.
[0023] The crowning resistance is further enhanced by constructing rim 10 as thin as practicable
(measured radially) since less force is needed to restrain a thin member from crowning.
A rim thickness ranging from 0.60 in. (0.15 cm) to 1/4 inch (0.64 cm) is preferred.
However, rim 10 should be thick enough to carry the residual rim stresses without
deforming, and thick enough to damp the thermal energy wave propagating inward from
the quench surface that would otherwise cause boiling of the coolant. In the shown
embodiment, rim 10 is approximately 90 mils (0.23 cm) thick.
[0024] The thin rim also improves the radial heat transfer from quench surface 23 through
the rim body to the coolant in channels 8, and thus provides a more uniform quench
rate across the width (measured axially) of rim 10. As a result of the improved crowning
resistance and more uniform quench rate, the casting wheel can be constructed to cast
filaments greater then 5 cm in width. The resultant casting wheel is not sensitive
to the width of the filament cast thereon, provided the width is less than the width
of the wheel quench surface. Thus, a wide filament, a narrow filament or even a simultaneous
grouping of narrow filaments can be cast on the casting wheel quench surface at random
locations without degrading the ability of the casting wheel to resist crowning. The
casting wheel of the invention could be constructed as wide as a roller-type wheel,
wherein the wheel width is greater than its diameter, and still retain its resistance
to crowning. As a practical matter, however, the wheel width is limited by the allowable
temperature rise of the coolant as it traverses the width through the coolant channels
8.
[0025] For example, a casting wheel having a stainless steel wheel core was constructed
in accordance with the invention and used to cast a filament of glassy metal alloy
approximately 4 inches (10.16 cm) wide. The physical profile of the quench surface
across the axial, width-of the wheel was measured before and during the casting operation.
Upon comparing the profiles, the measured amount of crowning was approximately 0.5
mils (0.00127 cm). In contrast, when a 4 inch (10.16 cm) glass metal ribbon was cast
using a casting wheel of ordinary construction, the measured amount of crowning effect
was approximately 4 mils (0.0102 cm). Thus, the casting wheel of the present invention
was approximately eight times more resistant to crowning than the ordinary casting
wheel.
[0026] Having thus described the invention in rather full detail, it will be understood
that these details need not be strictly adhered to but that various changes and modifications
may suggest themselves to one skilled in the art, all falling within the scope of
the invention as defined by the subjoined claims.
1. A chilled casting wheel, comprising:
(a) an annular wheel core member (7) having axially extending channels (8) formed
about a circumferential, outer peripheral surface (11) thereof and being adapted to
rotate about a concentric axis of rotation (28);
(b) a cylindrical, axially extending wheel rim member (10) concentrically connected
to said core peripheral surface (11) and having a preselected interference fit therewith
to provide a preselected residual, circumferential tensile stress within said rim;
and
(c) coolant means for directing a fluid coolant to the interior surface of said rim
and through said channels.
2. A chilled casting wheel, comprising:
(a) a hub shaft member (1) having a concentric axis of rotation (28) and two axial
end portions (2), each end portion delimiting an axial coolant chamber (3, 4) having
at least one coolant supply (5, 6) passage communicating radially therefrom;
(b) an annular wheel core member (7) concentrically connected to said hub shaft (1)
and adapted to rotate therewith, said wheel core having axially extending channels
(8) formed about an outer peripheral surface (11) thereof and two axially facing side
portions (9);
(c) a cylindrical, axially extending wheel rim member (10) concentrically connected
to said peripheral core surface (11) having a preselected interference fit therewith
to provice a residual, circumferential tensile stress within said rim; and
(d) two annular flange members (12) connected concentric with said hub shaft (1) and
adjacent to each of said core side portions (9) to delimit an annular coolant chamber
(13, 14) at each side of said wheel core which communicates with its respective coolant
supply passage (5, 6).
3. The casting wheel as recited in claim 1, wherein the thickness of said wheel rim
member
(10) measured radially ranges from 0.060 in. (0.15 cm) to 0.25 in. (0.64 cm).
4. The casting wheel as recited in claim 1, wherein said wheel rim member (10) has
a thickness measured radially of 90 mils (0.23 cm).
5. The casting wheel as recited in claim 2, wherein the thickness of said wheel rim
member (10) measured radially ranges from 0.060 in. (0.15 cm) to 0.25 in. (0.64 cm).
6. The casting wheel as recited in claim 2, wherein said wheel rim member (10) has
a thickness measured radially of 90 mils (0.23 cm).
7. The casting wheel as recited in claim 1 or 2, wherein said wheel rim (10) is shrink
fitted onto said wheel core to provide said interference fit.
8. The casting wheel as recited in claim 1 or 2, wherein said wheel core member (7)
is comprised of a material having a low coefficient of thermal expansion.
9. The casting wheel as recited in claim 1 or 2, wherein said wheel core (3) is comprised
of a metal alloy, which has a low coefficient of thermal expansion and consists essentially
of iron and nickel.
10. The casting wheel as recited in claim 1 or 2, wherein said wheel rim (10) is comprised
of a beryllium-copper alloy having a high thermal conductivity.
1. Gekühltes Gießrad mit
a) einem ringförmigen Radkernteil (7) mit sich axial erstreckenden Kanälen (8), die
nahe bei einer ringsum laufenden äußeren peripheren Oberfläche (11) desselben ausgebildet
sind und so angeordnet sind, daß sie um eine konzentrische Rotationsachse (28) rotieren,
b) einem zylindrischen, sich axial erstreckenden Radabschlußteil (10), das konzentrisch
mit der peripheren Oberfläche (11) des Kernteils verbunden ist und einen vorbestimmten
Festsetz darauf hat, um eine vorbestimmte restliche Umfangszugspannung in dem Abschlußteil
zu ergeben und
c) Kühleinrichtungen, die Kühlmittelfluid auf die Innenfläche des Abschlußteils und
durch die Kanäle führen.
2. Gekühltes Gießrad mit
a) einem Nabenwellenteil (1) mit einer konzentrischen Rotationsachse (28) und zwei
axialen Endabschnitten (2), wobei jeder Endabschnitt eine axiale Kühlenmittelkammer
(3, 4) mit wenigstens einem mit ihr radial in Verbindung stehenden Kühlmittelzufuhrdurchgang
(5, 6) begrenzt,
b) einem ringförmigen Radkernteil (7), das konzentrisch mit dieser Nabenwelle (1)
verbunden und so ausgebildet ist, daß es mit ihr rotiert, wobei das Radkernteil sich
axial erstreckende Kanäle (8), die nahe bei einer äußeren peripheren Oberfläche (11)
desselben ausgebildet sind, und zwei axial ausgerichtete Seitenabschnitte (9) besitzt,
c) einem zylindrischen, axial sich erstreckenden Radabschlußteil (10), das konzentrisch
mit der peripheren Kernteiloberfläche (11) verbunden ist und auf diesem einen vorbestimmten
Festsitz aufweist, um eine restliche Umfangszugspannung in dem Abschlußteil zu ergeben,
und
d) zwei ringförmigen Flanschteilen (12), die mit der Nabenwelle (1) und nahe jedem
der Kernseitenabschnitte (9) konzentrische verbunden sind, um eine ringförmige Kühlmittelkammer
(13, 14) auf beiden Seiten des Radkernteils und in Verbindung mit ihrem jeweiligen
Kühlmittelzufuhrdurchgang (5, 6) zu begrenzen.
3. Gießrad nach Anspruch 1, bei dem die Dicke des Radabschlußteils (10), radial gemessen,
im Bereich von 0,060 inch (0,15 cm) bis 0,25 inch (0,64 cm) liegt.
4. Gießrad nach Anspruch 1, bei dem das Radabschlußteil (10) eine Dicke, radial gemessen,
von 90 mil (0,23 cm) hat.
5. Gießrad nach Anspruch 2, bei dem die Dicke des Radabschlußteils (10), radial gemessen,
im Bereich von 0,060 inch (0,15 cm) bis 0,25 inch (0,64 cm) liegt.
6. Gießrad nach Anspruch 2, bei dem das Radabschlußteil (10) eine Dicke, radial gemessen,
von 90 mil (0,23 cm) hat.
7. Gießrad nach Anspruch 1 oder 2, bei dem das Radabschlußteil (10) auf dem Radkernteil
einen Schrumpfsitz hat, um den Festsetz zu ergeben.
8. Gießrad nach Anspruch 1 oder 2, bei dem das Radkernteil (7) aus einem Material
mit niedrigem Wärmeausdehnungskoeffizienten besteht.
9. Gießrad nach Anspruch 1 oder 2, bei dem das Radkernteil (7) aus einer Metallegierung
besteht, die einen niedrigen Wärmeausdehnungskoeffizienten hat und im wesentlichen
aus Eisen und Nickel besteht.
10. Gießrad nach Anspruch 1 oder 2, bei dem das Radabschlußteil (10) aus einer Beryllium-Kupfer-Legierung
mit einer hohen Wärmeleitfähigkeit besteht.
1. Une roue de coulée refroidie comprenant:
a) un noyau de roue annulaire (7) sur la surface périphérique extérieure circonférentielle
(11) duquel sont formés des canaux (8) s'étendant axialement et qui est agencé pour
tourner autour d'un axe de rotation concentrique (28);
b) une jante de roue cylindrique (10) s'étendant axialement montée concentriquement
sur ladite surface périphérique (11) du noyau sur laquelle elle est adaptée avec un
ajustage serré présélectionné pour assurer l'existence d'une contrainte de tension
circonférentielle résiduelle pré- sélectionée dans ladite jante; et
c) des moyens de refroidissement pour envoyer un fluide de refroidissement contre
la surface intérieure de ladite jante et dans lesdits canaux.
2. Une roue de coulée refroidie comprenant:
a) un arbre de moyeu (1) ayant un axe de rotation concentrique (28) et deux parties
d'extrémité axiales (2) chaque partie d'extrémité délimitant une chambre axiale (3,
4) à fluid de refroidissement qui comporte au moins un passage (5, 6) d'alimentation
en fluide de refroidissement qui s'étend radialement à partir d'elle:
b) un noyau de roue annulaire (7) monté concentriquement sur l'arbre de moyeu (1)
et agencé pour tourner avec lui, ledit noyau de roue comportant des canaux (8) s'étendant
axialement formés sur sa surface périphérique extérieure (11) et deux parties latérales
(9) orientées axialement;
c) une jante de roue cylindrique (10) s'étendant axialement montée concentriquement
sur ladite surface périphérique (11) du noyau sur laquelle elle est adaptée avec un
ajustage serré présélectionné pour assurer l'existence d'une contrainte de tension
circonférentielle résiduelle présélectionnée dans ladite jante; et
d) deux joues annulaires (12) montées concentriquement avec ledit arbre de moyeu (1)
et chacune adjacente à l'une desdites parties latérales (9) du noyau pour délimiter
une chambre annulaire (13, 14) à fluide de refroidissement de chaque côté dudit noyau
de roue qui communique avec son passage d'alimentation en fluide de refroidissement
respectif (5, 6).
3. La roue de coulée telle que revendiquée dans la revendication 1, dans laquelle
l'épaisseur de ladite jante (10) de roue mesurée radialement est comprise entre 0,060
pouce (0,15 cm) et 0,25 pouche (0,64 cm).
4. La roue de coulée telle que revendiquée dans la revendication 1, dans laquelle
ladite jante (10) de roue a une épaisseur mesurée radialement de 90 millipouces (0,23
cm).
5. La roue de coulée telle que revendiquée dans la revendication 2, dans laquelle
l'épaisseur de ladite jante (10) de roue mesurée radialement est comprise entre 0,060
pouce (0,15 cm) et 0,25 pouce (0,64 cm).
6. La roue de coulée telle que revendiquée dans la revendication 2, dans laquelle
ladite jante (10) de roue a une épaisseur mesurée radialement de 90 millipouces (0,23
cm).
7. La roue de coulée telle que revendiquée dans la revendication 1 ou 2, dans laquelle
ladite jante (10) de roue est ajustée par retrait sur ledit noyau de roue pour assurer
ledit ajustage serré.
8. La roue de coulée telle que revendiquée dans la revendication 1 ou 2, dans laquelle
le noyau (7) de roue est fabriqué en une matière ayant un faible coefficient de dilatation
thermique.
9. La roue de coulée telle que revendiquée dans la revendications 1 ou 2, dans laquelle
le noyau (7) de roue est fabriqué en un alliage métallique qui a un faible coefficient
de dilatation thermique et est composé essentiellement de fer et de nickel.
10. La roue de coulée telle que revendiquée dans la revendication 1 ou 2, dans laquelle
la jante (10) de roue est fabriquée en un alliage de cuivre au béryllium ayant une
conductivité thermique élevée.