Patent Grant
10434568
Casting is an old and well-known art in which liquefied materials are poured or injected into a mold which has a cavity of a desired shape. The liquefied materials are then allowed to solidify to create a cast article. Metal casting is one type of casting in which molten metals are introduced into a mold cavity at high temperatures and then allowed to solidify as the metals cool. The rate and pattern of cooling can affect the solidification process can directly affect the structure of the final cast article. For example, in some cases portions of a casting may begin to solidify at many different locations, leading to multidirectional solidification patterns within the casting. In other cases, premature cooling or cooling at undesired rates can result in undesirable microstructures within the casting or may clog or otherwise block portions of a mold cavity resulting in an unfinished or partial casting.
Solidification of a molten material within a mold cavity most frequently begins when the molten material first contacts the side walls or other inner surfaces of the mold cavity. Because molten materials are usually much hotter than the mold itself, heat quickly escapes from the molten material into the mold upon first contact. Once the material first contact the mold wall, solidification can spread rapidly through the molten material throughout the cavity. For example, molten metals exhibit an extremely high rate of heat loss and once solidification begins, an entire amount of molten metal within a mold can freeze almost instantaneously. The period of time extending from the first introduction of the molten material until complete solidification is often referred to as the dwell time. As will be appreciated, dwell times can be extremely short for molten materials, especially for molten metals, and sometimes may only last for a few seconds or even less than a second (e.g., milliseconds).
In some cases, it can be helpful to extend the dwell time of a molten material. For example, lengthening the dwell time may ensure adequate time for filling a mold cavity before solidification is complete or may promote the growth of desirable grain patterns in the solidifying material. In addition, a longer dwell time may facilitate additional activities during the casting process. As an example, when casting composite materials, extending the dwell time can allow more flexibility in positioning inserts, preforms, and other composite materials within the casting before solidification is complete.
Past efforts to extend dwell time include a few different approaches. Some have tried to increase dwell time by minimizing the temperature difference between surface of the mold cavity and the molten material being introduced into the mold. Some efforts included heating the mold to a temperature closer to that of the molten material. Other efforts included lowering the temperature of the molten material to a temperature closer to that of the molten material. While these efforts have been somewhat helpful, they have not been practical because increasing the temperature of the mold can consume large amounts of energy and may be inherently limited by the melting point of the mold material.
Some embodiments of the invention provide a method for casting an article. The method comprises spray-depositing a thermal insulator coating onto a surface of a mold cavity, and introducing a molten material into the mold cavity and in contact with the thermal insulator coating. In the present embodiments, the molten material within the mold cavity remains in a molten state for a predetermined dwell time.
In certain embodiments, the invention provides a method for casting an article. The method comprises spray-depositing a thermal insulator coating onto a surface of a preform or insert, positioning the preform or insert into a mold cavity, and introducing a molten material into the mold cavity and in contact with the thermal insulator coating. In the present embodiments, the thermal insulator coating isolates the preform or insert from the molten material for a predetermined dwell time.
Certain embodiments of the invention provide a method for casting an article. In the present embodiments, the method includes: i) identifying a surface x and a surface y in a mold cavity (the surface x is a surface desiring to have a longer isolation time from molten material than the surface y), ii) spray-depositing a first thermal insulator coating onto the surface x, and iii) spray-depositing a second thermal insulator coating onto the surface y. In the present embodiments, the first thermal insulator coating preferably is thicker than the second thermal insulator coating.
In some embodiments, the invention provides a system for applying a coating onto a surface of a mold cavity or a casting insert or a casting preform. The system includes a mixing vessel, a pump, and a spray applicator. The spray applicator has a spray nozzle with concentric inner and outer flow paths. In the present embodiments, the system preferably is configured such that: i) the pump moves a fibrous coating mixture comprising liquid and fibers from the mixing vessel, to the spray nozzle apparatus, through the inner flow path, and out of the spray nozzle, while simultaneously ii) a gas flow is sprayed through the outer flow path and out of the spray nozzle.
Some embodiments of the invention provide a method of applying a thermal insulator coating onto a surface of a mold cavity or a casting insert or a casting preform. In the present embodiments, the method involves spraying a fibrous coating mixture onto the mold cavity or the casting insert or the casting preform so as to form the thermal insulator coating. Preferably, the thermal insulator coating includes fibers and has (e.g., bounds or defines) internal thermally insulative gas spaces.
These and various other features and advantages will be apparent from a reading of the following detailed description.
The following drawings illustrate particular embodiments of the present invention and therefore do not limit the scope of the invention. The drawings are not to scale (unless so stated) and are intended for use in conjunction with the explanations in the following detailed description. Embodiments of the present invention will hereinafter be described in conjunction with the appended drawings, wherein like numerals denote like elements.
The following detailed description is exemplary in nature and is not intended to limit the scope, applicability, or configuration of the invention in any way. Rather, the following description provides some practical illustrations for implementing exemplary embodiments of the present invention. Examples of constructions, materials, dimensions, and manufacturing processes are provided for selected elements, and all other elements employ that which is known to those of ordinary skill in the field of the invention. Those skilled in the art will recognize that many of the noted examples have a variety of suitable alternatives.
Embodiments described herein are generally related and applicable to casting processes, including metal casting. Many examples described herein are related to or in various ways address heat transfer from the molten material that is introduced into a mold cavity. For example, some embodiments discuss heat transfer from molten materials into the surrounding mold cavity walls, shot sleeves, shot tips, and/or other parts of different kinds of molds. Also, some embodiments discuss heat transfer from molten material into various preforms and/or inserts within a composite casting. Some embodiments are directed to changing heat transfer properties through the use of insulating materials.
In addition, some embodiments are directed to controlling and/or changing the behavior of molten materials as they approach surfaces within the mold cavity such as the surfaces of inserts, preforms, and other objects within the mold cavity as well as the inner walls of the mold cavity itself. Also, some embodiments discuss materials that may be used to affect heat transfer within the casting process, and some embodiments describe thermally insulating materials that can be useful for casting processes. Some embodiments describe methods for making or manufacturing thermally insulating materials that can be used to address heat transfer in a casting process. Some embodiments describe methods for using some types of insulating materials within different casting processes, as well as systems that are provided to practice the methods. Of course, it should be appreciated that the embodiments described herein are examples of different products, articles, systems, and/or methods, and are not meant to limit the scope of possible embodiments or their application.
The ceramic fiber material can include a number of different types of ceramic fiber materials. In some cases, the ceramic fiber material includes a mixture of ceramic fibers. In some embodiments, the ceramic fiber material includes ceramic fibers from a polycrystalline fiber blanket, such as the Saffil LD mat. In other embodiments, the ceramic fiber material includes ceramic fibers from a refractory ceramic fiber blanket, such as the Kaowool mat. Other commercial sources for ceramic fibers cab include Carbon Fiber, Nextel Fiber and 3M Fibers.
The liquid can also include a number of different materials. In some cases, the liquid comprises, consists essentially of or consists of water. In some embodiments, the liquid comprises, consists essentially of or consists of water and a release agent. The release agent can generally be any agent that has increased lubricity such that it helps to release a solidified, cast article from a mold cavity. In some cases, the release agent can include polymer, wax, oil, ceramic, talc and/or graphite. Some molten materials are prone to sticking or even soldering to the mold cavity. As such, when using such sticky molten materials, it can be desirable to include a release agent in the liquid.
In certain embodiments, the liquid comprises, consists essentially of or consists of water and a release agent in a water-to-release agent ratio of between about 4:1 to about 50:1 measured on a volumetric basis. The ratio can vary depending on the type of release agent used and/or the type of molten material used.
In some embodiments, the invention provides a system for applying a coating onto a surface of a mold cavity or a casting insert or a casting preform. The system generally includes a mixing vessel 2608, a pump 2704, and a spray applicator 2802. Reference is made to
By discharging from the nozzle 2806 a high velocity gas stream that surrounds a slurry flow stream, the slurry can be accelerated toward the desired surface due to interaction between the two flow streams (e.g., due to action of the high velocity outer gas stream on the inner slurry stream emanating from the nozzle). More will be said of this later.
Thus, the illustrated spray nozzle 2806 has two concentric discharge orifices, a slurry discharge orifice 2810, and a gas discharge orifice 2812. Preferably, the slurry orifice 2810 is the centermost one of the two concentric orifices. The illustrated gas orifice 2812 completely surrounds the slurry orifice 2810, although this is not strictly required. Typically, the slurry orifice 2810 will have a larger cross-sectional area than does the gas orifice 2812. In the non-limiting design illustrated, the gas discharge orifice 2812 has an annular cross-sectional shape, while the slurry discharge orifice 2810 has a circular cross-sectional shape. Here, the annular gas discharge orifice 2812 entirely surrounds the circular slurry discharge orifice 2810. While these details are currently preferred, they are not required in all embodiments.
A slurry intake (e.g., hose, pipe, tube, or other intake line) 2804 is connected to the spray applicator 2802 to supply a flow of slurry to the applicator. In the embodiment shown, the slurry intake 2804 is located at a rear end region of the spray applicator 2802, and the nozzle 2806 is at an opposite, front end region of the applicator. It is to be appreciated, however, that this is merely one possible applicator configuration.
The spray applicator 2802 of
In the illustrated spray applicator 2802, compressed gas is supplied to the gas intake 2808. Compressed air, for example, can be supplied at about 15-30 psi, and the volume of the supplied air can be metered. The compressed air enters the spray applicator 2802 via the gas intake 2808, flows through the manifold 2818, along the outer flow path 2807, and out the gas discharge orifice 2812. The supply of pressurized air can be flowed through the spray apparatus 2802 to its gas discharge orifice 2812, while simultaneously the pump 2704 is operated to supply a flow of slurry to the nozzle 2806. This can produce a high velocity, low pressure air flow, which is discharged from the gas orifice 2812, while a low volume, low pressure slurry flow is simultaneously discharged from the slurry orifice 2810. As the slurry exits the nozzle 2806 together with the surrounding gas stream, the slurry is accelerated somewhat by the gas stream. Moreover, the flows of gas and slurry may mix somewhat due to the geometry of the spray nozzle and the dynamics of the resulting air/slurry discharge.
As shown in
In the embodiments of
The pick-up port 2612 preferably has a smooth bore and an outlet end region 2610 spaced outwardly from the exterior of the mixing vessel 2608. This is perhaps best seen in
The system includes a pump 2704 configured to move the fibrous coating mixture from the mixing vessel 2608 to the spray applicator 2802. Given the fibrous nature of the coating mixture, the pump 2704 preferably is a positive displacement pump, such as a peristaltic pump. One suitable peristaltic pump is the 913 series MityFlex® Variable Speed Peristaltic Pump, which can be purchased commercially from Anko Products of Bradenton, Fla., USA.
Thus, the system preferably includes a slurry line (e.g., tubing) configured to deliver the fibrous coating mixture from the mixing vessel 2608 to the pump 2704, and from the pump to the spray applicator 2702. The slurry line can take different forms, but preferably involves as few segments as possible, so as to minimize the number of interfaces/fittings where fibers in the slurry may get caught and build-up.
The invention also provides methods of applying a coating onto a desired surface. In some embodiments, the method involves applying a thermal insulator coating onto a desired surface of a mold or insert or preform. Preferably, the coating application is done by spraying a coating mixture onto the desired surface. The coating, for example, can advantageously be a thermal insulator coating. In some cases, the sprayed coating mixture is a fibrous coating mixture, and the resulting thermal insulator coating comprises fibers and has (e.g., bounds, contains, surrounds, or defines) internal thermally insulative gas spaces (e.g., “air gaps”).
The spraying can advantageously be done using a spray applicator 2802 comprising a spray nozzle 2806 with concentric inner 2803 and outer 2807 flow paths. As noted above, the fibrous coating mixture preferably comprises liquid and fibers. The process may involve pumping the fibrous coating mixture through the inner flow path 2803 and out of the spray nozzle 2806, while simultaneously flowing a gas stream through the outer flow path 2807 and out of the spray nozzle. As discussed previously, this can result in a mix of slurry material and gas emanating from the spray nozzle 2806.
The spray applicator 2802 can advantageously include a gas intake 2808 and a pressure reduction manifold chamber 2818. In such cases, the gas intake 2808 preferably opens into the pressure reduction manifold chamber 2818. As shown in
With continued reference to
In some of the present embodiments, the method comprises mixing liquid and fibers in a mixing vessel 2608 so as to create the fibrous coating mixture. The liquid can comprise water, optionally together with a conventional mold release agent, as is commercially available from numerous suppliers, including Chem-Trend LP., of Howell, Mich., U.S.A.
The mixing can advantageously be done using a high-sheer mixer comprising a high-sheer mixer head 2606, optionally comprising a generally disc-shaped high-sheer mixer blade. One suitable high-sheer mixer is the RELMIXER product, which is commercially available from REL, Inc. of Calumet, Mich., USA. Preferably, the mixing vessel 2806 has a cylindrical interior sidewall 2609 bounding an interior 2603 of the vessel, as exemplified in
As noted above, the method involves mixing liquid and fibers together in a mixing vessel 2608 so as to create the fibrous coating mixture, followed by pumping the fibrous coating mixture to a spray nozzle 2806. Given the fibrous nature of the coating mixture, the pumping preferably is done using a positive displacement pump, such as a peristaltic pump.
In some cases, the initial mixture includes a liquids-to-solids weight ratio of about 5% to 10% (i.e., a liquids-to-solids ratio from about 5:100 to about 10:100). Once the effluent is driven off, the solids-to-liquids ratio would be 100% to 0%.
The thickness of the coating deposited can be varied to accommodate the requirements of different applications. In some cases, the fibrous coating mixture is sprayed onto the desired surface so as to deposit the thermal insulator coating at a thickness of between 0.01 inch and 0.2 inch, such as between about 0.012 inch and about 0.18 inch. In some embodiments, the thickness of the coating is between about 0.015 inch and about 0.030 inch. It is to be appreciated, however, that lesser or greater thicknesses may be preferred.
In some embodiments, a target density for the spray-on thermal insulator can be between about 7% to about 20% of volume. That is, when the coating has been allowed to dry, the ceramic fibers occupy between about 7% and about 20% of volume of the coating. In some cases, a target density of about 15% is desirable. In other cases, a target density of between about 5% and about 10% is desirable, e.g., when using ceramics fibers with a relatively long fiber length. In still other cases, a target density of between about 15% and about 25% is desirable, e.g., when using ceramics fibers with a relatively short fiber length. The density of the spray-on thermal insulator can be impacted by the composition of the slurry (including the ratio of liquid to ceramic fibers) and the relative flow rates of the air to the slurry through the nozzle.
Ceramic fibers of relatively long length tend to create more undulation for the resulting coating. By contrast, ceramic fibers of relatively short length tend create a smoother surface for the coating.
The optimum balance of air flow rate and slurry flow rate can depend upon a number of variables, including the following: (i) the particular fibers that are used in the slurry; (ii) the ratio of liquid to fibers used in mixing the slurry; (iii) the air pressure of the compressed air introduced into the nozzle inlet 2808; and (iv) the target density for the resulting coating. In one non-limiting example, a slurry flow rate of between about 2.5 fluid ounces (about 75 cubic centimeters) per minute and about 3.5 fluid ounces (about 105 cc) per minute is used.
It is contemplated that a number of different types of fibers can be used. In some embodiments, the fibers comprise ceramic, e.g., oxide fibers. If desired, the fibers can comprise silica fibers, alumina fibers, or both. As just one example, ceramic fibers can be obtained from a polycrystalline fiber blanket, such as the Thermal Ceramics Saffil LD Mat. If desired, the ceramic fibers can be from a refractory ceramic fiber blanket, such as the Thermal Ceramics Kaowool mat. Other commercial sources for ceramic fibers include Carbon Fiber, Nextel Fiber and 3M Fibers. In some embodiments, the ceramic fiber mat can be chopped prior to combining with the liquid.
When spraying onto intricate details of a mold cavity, it may be desirable to use conventional computer-aided robotics. Further, it is advantageous to employ rapid repeatable robotic application without human intervention.
The thermal insulator coating can be used in various casting methods and systems as will be further described herein. In each of these systems and methods, the thermal insulator coating can be a thermal insulator coating or a spray-on thermal insulator having a composition as already described above. Also, any steps of depositing a thermal insulator coating can be a step of spraying or spray-depositing the thermal insulator coating using equipment as already described above.
In other embodiments further described below, the thermal insulator is not a coating but can be a thermal blanket as described in U.S. provisional patent application No. 61/623,532 filed Apr. 12, 2012, entitled Thermal Isolation for Casting Articles or in U.S. patent application Ser. No. 13/840,423 filed concurrently herewith, entitled Thermal Isolation for Casting Articles, the entire contents of each of which are incorporated herein by reference. Some or all of the embodiments applicable to thermal blankets in these related application may also be applicable to the spray-on thermal insulator coatings described herein.
Further, some Figures show all surfaces of an article (mold cavity, preform, insert, etc.) bearing a thermal insulator coating and other Figures show only a single surface or only some surfaces bearing a thermal insulator coating. However, skilled artisans will understand that in each of these Figures, the thermal insulator coating can be provided on a single surface, on some surfaces or on all surfaces of an article. Also, some Figures show a single layer of thermal insulator coating on a surface. However, skilled artisans will understand that this single layer can instead be a plurality of layers that make up the coating. Likewise, the single layer or plurality of layers can each have any desired thickness.
As used herein, the term “preform” or “casting preform” is used to reference a material that can be infiltrated with a molten material. Also, the term “insert” or “casting insert” is used herein to indicate a piece of material that would not be infiltrated. For example, an insert might be solid material like a piece of steel. In some cases, the preform is a porous preform, a variable density preform or a porous variable density preform wherein the preforms are suitable for infiltration casting. The preform can include for example, ceramic particles, continuous or discontinuous ceramic fibers or a combination thereof.
The source of molten material 18 can include any desired molten material known in the art usable in methods for casting articles. In some cases, the molten material can include at least one metal (e.g., in elemental, compound, or alloy forms). In certain cases, one or more metals including aluminum, magnesium, and/or steel can be used. Further, in some cases, the molten material can include a particulate material. One example of such a material is Duralcan, which includes SiC particles suspended in aluminum.
The mold 12 can include any desired mold known in the art and the mold cavity 14 can include any desired shape. In some cases, the mold is a gravity casting mold. In other cases, the mold is a squeeze casting mold. In a squeeze casting mold, a first portion presses against a second portion to apply pressure to materials inside the mold cavity. In other cases, the mold includes a shoot sleeve and plunger that can be actuated to inject molten material into the mold cavity. In some cases, the mold 12 includes contours in the mold cavity surface. Such contours can include voids, crevices, depressions, recesses, runs that form surface features in a cast article.
The mold includes a moving top wall or plunger 24 that moves downward to apply pressure to the molten materials within the cavity. Upon applying pressure, the molten material infiltrates and substantially disintegrates the thermal insulating coatings 20a, 20b, 20c, 20d, 20e.
The use of a metal cladding can be desirable for a number of reasons. First, metal cladding can be desirable to simplify handling of a coated preform 16 or insert, such that disruption of the thermal insulator coating can be minimized during handling. The metal cladding can also be desirable to provide protection to the thermal insulator coating that surrounds the preform during casting. For example, in certain casting applications, molten material can move within a mold at a relatively rapid velocity. Such a rapidly moving molten material can erode a thermal insulator coating from a preform or insert as the molten material moves through the mold and across the thermal insulator coating. The metal cladding helps to prevent the thermal insulator coating from immediately eroding. Likewise, molten material can sometimes degrade the preform or insert material itself and the thermal cladding can help to protect this.
According to some embodiments, an encapsulated preform can include a ceramic tile. Coating a ceramic tile with a thermal insulator coating, and providing an encapsulating cladding can help minimize the thermal shock that can result when a molten material comes into contact with the ceramic tile. In some embodiments, a ceramic tile can crack if it is permitted to come into direct contact with a molten material, whereas an insulated and encapsulated ceramic tile may not as easily crack.
In some embodiments, encapsulated preforms can be used with a pressure casting method. One or more encapsulated preforms can be placed within a mold cavity and molten material can then be introduced into the cavity. Pressure can then be applied to the molten material, which causes the metal cladding to soften and eventually melt, permitting the molten material to flow into contact with and infiltrate both the thermal insulator coating and preform.
In each of the methods and systems described above, the thermal insulator coating serves to isolate one surface from another surface. In some cases, the thermal insulator coating isolates molten material from an inner surface of a mold cavity. In other cases, the thermal insulator coating isolates molten material from a preform or insert surface.
In some embodiments, the isolation lasts long enough to allow molten material in the mold cavity to remain in a molten state until a specified portion of the mold cavity is filled with molten material. In certain cases, the isolation lasts long enough to allow the molten material in the mold cavity to remain in a molten state until substantially the entire mold cavity is filled with the molten material. In other cases, the isolation lasts long enough to allow the molten material in the mold cavity to contact substantially all surfaces in the mold cavity. In yet other cases, the isolation lasts long enough to allow molten material in the mold cavity to remain in a molten state until a specified pressure is applied to the molten material.
In some embodiments, the thermal insulator coating can be used to help isolate a small space within a mold or a passageway leading into a mold such as a shot sleeve or shot tip. As is known, molten materials injected into a mold through small passageways such as a shot sleeve and shot tip can sometimes solidify while in the small space before the materials even reach the mold cavity. Such premature solidifying can sometimes cause the molten material to build up on the interior surface of the passageway and can sometimes cause partial or complete blocking of the passageway. Thus, in some embodiments, the thermal insulator coating is positioned within a passageway in order to isolate the passageway.
According to some embodiments, the thermal insulator coating can be applied to extend the dwell time of a molten material. In some cases, the dwell time can be on the order of minutes rather than the order of seconds, milliseconds, and smaller units. In some cases, the thermal insulator coating can be applied to extend the dwell time of a molten material to 3, 4, or 5 or more minutes. Such an increased dwell time can provide several advantages. For example, a prolonged or increased dwell time can provide added time that is useful for arranging tiles, inserts, performs, and other types of objects within the mold cavity. With some past methods, multiple people have been needed to insert materials into a mold cavity because of the very quick solidification rates. In contrast, use of the thermal insulator coating may require fewer people and/or provide dwell time for increasing the accuracy of preform positions, ensuring performs are distributed with spacing as desired, etc. This can be useful for casting high performance materials and may make it easier to selectively change the performance of a casting by tailoring properties of the casting during the increased dwell time.
The thermal insulator coating can be applied to have a dried thickness of less than about 0.0625 inches. In some embodiments, the dried thickness can be between about 0.0001 inches and about 0.0625 inches. In some cases, the dried thickness can be chosen to be between about 0.03 inches and about 0.06 inches. According to some embodiments, the dried thickness can be about 0.03 inches. In some embodiments, the dried thickness of a spray-on thermal insulator can range from a trace amount to a thickness of about 0.236 inches (about 6 mm). Accordingly, the thermal insulator coating can be applied at very small thicknesses.
Also, in some embodiments, the thermal insulator coating can be provided at a desired thickness such that it substantially disintegrates at a specified point in the casting process. In some cases, the thermal insulator coating disintegrates when it comes into contact with molten material. In other cases, the thermal insulator coating is sufficiently strong to withstand contact with a molten material but disintegrates after pressure is applied to molten material in the mold. After pressure is applied, the molten material infiltrates the thermal insulator coating and breaks it apart. In many cases, regardless of when the thermal insulator coating disintegrates, when the cast is removed from the mold after casting is completed, the thermal insulator coating is not visible to the naked eye.
Further, in some embodiments, the thermal insulator coating can be applied to control a direction of solidification within the casting. For example, in some cases, a first thermal insulator coating can be applied to an inner surface of the mold cavity. Next, an amount of molten material can be introduced into the mold cavity. After introducing the molten material, a second thermal insulator coating can be applied to a top surface of the molten material. In some cases, one of the first and second thermal insulator coatings is thinner than the other, which may provide control of the direction of solidification. For instance, the thinner coating can break down before the thicker coating does. As such, heat is transferred more readily through the thinner coating, leading to the start of solidification at the thinner coating. Solidification can progress through the molten material until it reaches the thicker coating.
In other embodiments, the thermal insulator coating can be applied to create a functional gradient within a casting. Some types of molten materials include both a molten metal and a particulate material or ceramic fiber material. In some cases, the thermal insulator coating is positioned within the mold such that as the molten material infiltrates the thermal insulator coating, the particulate material or ceramic fiber material tends to have difficulty passing through the thermal insulator coating. Accordingly, a coating or amount of the particulate material or ceramic fiber material tends to build up at the interface of the thermal insulator coating. One example of a molten material that includes a fractional amount of particulates and/or fibers is Duralcan, which is manufactured by Rio Tinto Alcan. For example, in one possible use, the Duralcan material may be 30 vol. fraction as the material is introduced into the mold cavity and may be up to about 60 vol. fraction at the interface of the thermal insulator coating due to the difficulty in passing the particulate matter through the thermal insulator coating. In some cases, the molten material may then tailor back down to about 30 vol. fraction as it nears another side of the mold cavity, thus creating a functional gradient within the molten material.
In some cases, the thermal insulator coating can be applied to provide a casting process in which the mold can be operated at a colder temperature than might otherwise be used. Colder mold temperatures can, in turn, provide faster solidification times which may lead to improved solidification of the molten materials (e.g., finer grains, few long grains, fewer dendrite growths, etc.). In some cases, the methods can be used with a mold cavity having a room temperature (e.g., about 20° C.) as opposed to having a temperature closer to 250° C., which is typical for metal casting processes. Accordingly, some embodiments can provide material flow characteristics within a mold at room temperature that are substantially the same as characteristics typical of molds run at temperatures closer to 250° C., while also providing higher solidification or cooling rates.
Thus, embodiments of the invention are disclosed. Although examples have been described in considerable detail with reference to certain disclosed embodiments, the disclosed embodiments are presented for purposes of illustration and not limitation and other embodiments of the invention are possible. One skilled in the art will appreciate that various changes, adaptations, and modifications may be made without departing from the spirit of the invention and the scope of the appended claims.
This application claims priority to U.S. provisional patent application No. 61/623,532, filed Apr. 12, 2012, entitled Thermal Isolation for Casting Articles, and to U.S. provisional patent application No. 61/690,727, filed Jul. 3, 2012, entitled MMC with Enhanced Thermal Isolation. This application is also related to U.S. patent application Ser. No. 13/840,423, filed concurrently herewith, entitled Thermal Isolation for Casting Articles. Each of the referenced applications are hereby incorporated by reference herein in their entirety.
This invention was made with government support under contract DE-AR0000253 awarded by the U.S. Department of Energy. The government has certain rights in the invention.
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| Number | Date | Country | |
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| Number | Date | Country | |
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| 61623532 | Apr 2012 | US | |
| 61690727 | Jul 2012 | US |
