BACKGROUND OF THE INVENTION
Field of the Invention:
[0001] The present invention relates generally to an integrated crucible and mold for casting.
More particularly, the present invention provides a method for producing a one-piece
integrated crucible and invested mold for use in the casting of reactive metals, particularly
complex shapes thereof.
Description of the Related Art:
[0002] Melting and casting of reactive metals such as titanium or titanium aluminides is
difficult due to the molten metals reactivity with crucibles comprising of alumina,
zircon, or silicates which are typically used in casting metals such as iron, nickel
or aluminum. Turbocharger rotors are typically cast using nickel superalloy which
can be easily melted and cast using invested mold having a zircon facecoat and an
alumina-silicate crucible attached to the top of the mold. Molten titanium almninide
will rapidly react with the alumina-silicate crucible making casting impossible.
[0003] Candidate crucible materials include yttria (Y
2O
3), thoria (ThO
2), calcia (CaO) and other exotic rare earth oxides. Thoria is radioactive and suffers
from poor thermal shock resistance. For this reason it has not been exploited industrially.
However, yttria crucibles are very expensive, $50 to $100 The alumina-silicate crucibles
used for nickel superalloy castings are less than $1. Since titanium and titanium
aluminide castings compete with nickel castings in a wide variety of applications,
the high cost of yttria crucibles effectively prices titanium and titanium aluminide
castings out of the market. This is particularly important for cost sensitive applications,
for example automotive applications.
[0004] Calcia is also a potential refractory material for titanium and titanium aluminides
due to its thermal stability. US Patent No. 4,710,481 to Degawa et. al. discloses
melting titanium and titanium alloys in calcia crucibles. However, calcia is highly
hydrophilic and spontaneously hydrates in ambient levels of atmospheric moisture.
The hydration is accompanied by volume changes which cause cracking and spallation.
Calcia crucibles can spontaneously crack after only hours of exposure to atmospheric
moisture. For this reason calcia is an impractical material for a crucible in commercial,
industrial environments.
[0005] It is therefore desirable to provide industrially practical, low cost molds for the
casting of titanium and titanium aluminide metals which overcome the abovementioned
drawbacks. The invention would also find application for other reactive metal castings,
for example zirconium alloy castings. It is also desirable to provide a low cost,
industrially practical one piece crucible and investment mold for casting reactive
and non-reactive metals.
[0006] It is further desirable to provide a graphite or other inductively suscepting composite
crucible containing graphite which is directly attached to an invested mold for the
casting of γ-TiAl components and, specifically, to provide a method for producing
low cost investment castings of γ-TiAl turbocharger rotors.
SUMMARY OF THE INVENTION
[0007] To overcome the limitation of the prior art and obtain the desired qualities, the
present invention provides a graphite crucible attached directly to the top of an
invested mold in the shape of the complex molded part, a turbocharger rotor for the
specific embodiments disclosed herein, to form an integrated unit. A method for producing
the integrated crucible and mold is characterized by the steps of attaching an investment
pattern to a cylindrical graphite crucible and building an investment mold shell around
the pattern and a mating portion of the crucible. The mold shell is created by dipping
the pattern and crucible mating portion in an inert ceramic facecoat slurry, allowing
the dipcoat layer to partially dry and/or cure, applying a layer of ceramic stucco
over the dipcoat and laminating additional layers of dipcoat and stucco to achieve
the desired thickness mold shell.
[0008] The embodiment of the invention described in detail subsequently, provides a one
piece crucible/mold system suitable for casting a metal part in vacuum at temperatures
exceeding 1400°C.
[0009] The method of employing the apparatus of the invention for casting of complex components
takes advantage of the rapid melting and casting of the γ-TiAl to avoid carbon contamination
from the crucible. Carbon is a known contaminant of γ-TiAl. At low levels, i.e. under
2000 ppm (wt%) it is often added to improve creep properties of γ-TiAl. However, at
higher levels it strongly reduces the tensile ductility of γ-TiAl. The one piece graphite
crucible/investment mold prevents the deleterious contamination of γ-TiAl by the crucible
since the design allows for rapid melt times and low superheats, both of which minimize
the potential for carbon contamination.
BRIEF DESCRIPTION OF THE DRAWINGS
[0010] The details and features of the present invention will be more clearly understood
with respect to the detailed description and drawings in which:
FIG. 1 is a section elevation view of the integrated graphite crucible and invested
mold; and
FIG. 2 is a pictorial view of an exemplary turbocharger rotor manufacturable from
γ-TiAl using the present invention.
DETAILED DESCRIPTION OF THE INVENTION
[0011] An embodiment of the present invention is shown in FIG. 1. The integral crucible
and mold includes a cylindrical graphite sleeve 10 having a bottom 12 adapted to accommodate
attachment of a polystyrene invested mold pattern 14 having an attachment runner 15.
In the embodiment shown, the attachment runner is sealingly attached to the sleeve
with wax 16. The sleeve is sized to accommodate a desired meltstock billet 17. An
investment shell 18 is constituted by laminations of a facecoat slurry 20 and ceramic
stucco 22 (shown only over a portion of the section for clarity), which extend over
and adhere to a bottom mating portion of the graphite sleeve. After firing, which
results in vaporization of the pattern, the hardened shell laminate is fixedly attached
to the graphite sleeve forming an integral crucible and mold for casting of the desired
part. An aperture 24 in the bottom face of the sleeve provides a flow path for the
molten casting metal into the mold shell while the rim 26 retains the meltstock billet
in the crucible in a position for induction heating.
[0012] A method for creating and employing the apparatus of the present invention includes
the steps of attaching the polystyrene turbocharger wheel pattern to the cylindrical
graphite sleeve by dipping the top of the polystyrene pattern in hot wax and inserting
it into the recess in the bottom of the graphite sleeve. An investment shell is next
built around the polystyrene pattern and the lower portion of the sleeve. As embodied
herein, the investment mold process begins with dipping the pattern made of wax or
plastic having the shape of the desired casting in a facecoat slurry made from any
ceramic inert to γ-TiAl, for example, yttria or calcia. An appropriate slurry for
creating a calcia facecoat is disclosed in WO 97/43060 entitled Inert Calcia Facecoats
for Investment Casting of Titanium and Titanium-Aluminide Alloys having a common assignee
with the present application.
[0013] After allowing the dipcoat layer to partially dry and/or cure, alternate layers of
ceramic stucco and dipcoat are applied on both the pattern and the lower area of the
crucible until a shell of desired thickness is formed. The crucible/invested mold
is allowed to dry thoroughly, and then is fired at temperatures near 1000°C for a
period of no less than 0.5 hour in an oxidizing atmosphere such as air. The firing
results in the complete volatilization of the pattern in a manner familiar to those
skilled in the "lost wax" art.
[0014] The crucible/invested mold assembly is then transferred while still hot from the
furnace and placed in a casting chamber and evacuated. A cylindrical meltstock billet
of the casting metal is inserted in the crucible. The metal is next rapidly melted
by inductively heating the graphite crucible. Since graphite is a strong susceptor,
the crucible is quickly heated to the melting temperature of the γ-TiAl. The molten
metal falls directly into the attached invested mold with the assistance of gravity
with a minimum of superheat and hold time. The short hold time and low superheat prevents
significant contamination by carbon from the crucible. The short drop distance, attained
as a result of the one piece design of the crucible/investment mold, allows full fill
in thin sections. Greater drop distances, as would be required by two piece crucible/investment
mold systems result in poor fill due to cooling and premature solidification in the
fill tube area. After cooling, the cast metal, now in the shape of the original pattern
is removed from the pattern. An exemplary
EXAMPLE I
[0015] A turbocharger rotor pattern made polystyrene plastic was fitted to a recess in the
bottom of a graphite crucible using wax to join the pattern to the crucible. The plastic
was dipped in the facecoat slurry made from a yttria facecoat inert to γ-TiAl. After
allowing the dipcoat layer to partially dry and/or cure, alternate layers of ceramic
stucco and dipcoat were applied on both the pattern and the lower area of the graphite
crucible until a shell of desired thickness was formed. It was subsequently redipped
multiple times into backup coatings of flintgrains and alumina silicate powders to
form an integrated investment mold, shown schematically in Figure 1. The crucible/invested
mold containing the plastic turbocharger pattern was allowed to dry thoroughly, and
then was fired at temperatures near 1000°C for a period of 0.5 hour in air. The graphite
crucible/invested turbocharger mold assembly was then transferred while still hot
from the furnace, charged with the casting metal meltstock billet, placed under a
quartz bell jar and evacuated. The graphite crucible and metal were next heated by
induction resulting in melting of the metal. A drawing of the cast TiAl rotor made
from this process is shown in figure 2.
[0016] Having now described the invention in detail as required by the patent statutes.
those skilled in the art will recognize modifications and substitutions to the specific
embodiments disclosed herein. Such modifications and substitutions are within the
scope and intent of the present invention as defined in the following claims.
1. A method for producing an integral crucible and mold for casting of reactive metals
comprising the steps of:
attaching an investment pattern to a cylindrical graphite crucible sleeve;
forming an investment shell around the pattern and a mating portion of the crucible
sleeve;
firing the shell and attached crucible sleeve for complete cure of the shell and volatilization
of the pattern.
2. A method as defined in claim 1 wherein the step of attaching the investment pattern
to the crucible sleeve comprises:
dipping a mating portion of the pattern in hot wax; and
inserting the mating portion of the pattern into a recess in the graphite crucible
sleeve.
3. A method as defined in claim 1 wherein the step of forming comprises:
dipping the in pattern in a facecoat slurry;
allowing the dipcoat layer to partially dry or cure;
applying alternating layers of ceramic stucco and dipcoat on both the pattern and
the mating portion of the crucible sleeve until a shell of desired thickness is formed.
4. A method as defined in claim 3 wherein the step of applying alternating layers is
followed by a step of allowing the shell to dry thoroughly.
5. A method as defined in claim 1 wherein the pattern is polystyrene plastic.
6. A method as defined in claim 1 wherein the firing is accomplished at temperatures
near 100°C for a period of no less than 0.5 hour in an oxidizing atmosphere such as
air.
7. A method as defined in claim 3 wherein the step of applying alternating layers is
followed by the step of applying at least one laminating layer of flint grains and
alumina silicate powders.
8. A method as defined in claim 3 wherein the facecoat slurry forming an inert ceramic.
9. A method as defined in claim 8 wherein the inert ceramic comprises yttria.
10. A method as defined in claim 8 wherein the inert ceramic comprises calcia.
1. Verfahren zur Herstellung einer einteiligen Tiegel/Form-Anordnung zum Vergießen von
reaktiven Metallen, bei dem man:
ein Ausschmelzmodell an einer zylindrischen Graphittiegelhülle befestigt;
um das Modell und einen Paßteil der Tiegelhülle herum eine Ausschmelzschale herstellt;
die Schale und die daran befestigte Tiegelhülle zur vollständigen Härtung der Schale
und Verflüchtigung des Modells brennt.
2. Verfahren nach Anspruch 1, bei dem man beim Befestigen des Ausschmelzmodells an der
Tiegelhülle:
einen Paßteil des Modells in heißes Wachs taucht und
den Paßteil des Modells in eine Aussparung in der Graphittiegelhülle hineinschiebt.
3. Verfahren nach Anspruch 1, bei dem man im Herstellungsschritt:
das Modell in eine Überzugsaufschlämmung eintaucht;
die durch Eintauchen aufgebrachte Überzugsschicht antrocknen oder anhärten läßt und
sowohl auf das Modell als auch auf den Paßteil der Tiegelhülle alternierende Schichten
aus Keramikstuck und durch Eintauchen aufgebrachtem Überzug aufbringt.
4. Verfahren nach Anspruch 3, bei dem man nach dem Aufbringen alternierender Schichten
die Schale gründlich trocknen läßt.
5. Verfahren nach Anspruch 1, bei dem man als Modell Polystyrol-Kunststoff einsetzt.
6. Verfahren nach Anspruch 1, bei dem man das Brennen bei Temperaturen nahe 100°C über
einen Zeitraum von mindestens 0,5 Stunden in einer oxidierenden Atmosphäre wie Luft
durchführt.
7. Verfahren nach Anspruch 3, bei dem man nach dem Aufbringen alternierender Schichten
mindestens eine Laminierschicht aus Flintkörnern und Aluminiumsilicatpulvern aufbringt.
8. Verfahren nach Anspruch 3, bei dem die Überzugsaufschlämmung eine inerte Keramik bildet.
9. Verfahren nach Anspruch 8, bei dem die inerte Keramik Yttriumoxid enthält.
10. Verfahren nach Anspruch 8, bei dem die inerte Keramik Calciumoxid enthält.
1. Procédé de production d'un creuset et d'un moule d'un seul tenant pour couler des
métaux réactifs, comprenant les étapes consistant à:
fixer un modèle perdu à une cuvette de creuset en graphite cylindrique;
former une coquille perdue autour du motif et d'une partie concourante de la cuvette
de creuset;
cuire la coquille et la cuvette de creuset fixée pour achever le durcissement de la
coquille et volatiliser le modèle.
2. Procédé selon la revendication 1 dans lequel l'étape consistant à fixer le modèle
perdu à la cuvette de creuset comprend:
le fait de tremper une partie concourante du motif dans de la cire chaude; et
le fait d'insérer la partie concourante du motif dans un creux ménagé dans la cuvette
de creuset en graphite.
3. Procédé selon la revendication 1 dans lequel l'étape de formation comprend:
le fait de tremper le modèle dans une suspension d'apprêt;
le fait de laisser la couche de coulis sécher ou durcir partiellement;
le fait d'appliquer des couches alternées de stuc de céramique et de coulis à la fois
sur le modèle et sur la partie concourante de la cuvette de creuset jusqu'à ce qu'une
coquille d'épaisseur voulue soit formée.
4. Procédé selon la revendication 3 dans lequel l'étape consistant à appliquer des couches
alternées est suivie d'une étape consistant à laisser sécher complètement la coquille.
5. Procédé selon la revendication 1 dans lequel le motif est du plastique de polystyrène.
6. Procédé selon la revendication 1 dans lequel la cuisson est réalisée à des températures
proches de 100°C pendant pas moins de 0,5 heure dans une atmosphère oxydante telle
que l'air.
7. Procédé selon la revendication 3 dans lequel l'étape consistant à appliquer des couches
alternées est suivie de l'étape consistant à appliquer au moins une couche de stratification
de grains siliceux et de poudres de silicate d'alumine.
8. Procédé selon la revendication 3 dans lequel la suspension d'apprêt forme une céramique
inerte.
9. Procédé selon la revendication 8 dans lequel la céramique inerte comprend de l'oxyde
d'yttrium.
10. Procédé selon la revendication 8 dans lequel la céramique inerte comprend de la chaux.