Patent Application
20090160092
The present disclosure relates to a precision casting process, and more particularly, to a sand casting process for making precision parts.
Casting is a manufacturing process by which a liquid or a slurry material (such as a metal, a ceramic slurry, or a plastic) is introduced into a mold, allowed to solidify within the mold, and then separated from the mold to make a part. Casting may be used for making parts of complex shape that would be difficult or uneconomical to make by other methods, such as machining, stamping, forging, extrusion, etc. Sand casting is a common casting process. In typical sand casting, molten metal is poured into a mold cavity formed out of sand (natural or synthetic) housed in a box called a flask. The mold cavity is formed in the sand by using a pattern which is an approximate duplicate of the part to be cast. One or more sand shapes, called “cores,” may be used in the mold cavity to produce internal features (such as holes or internal passages) of the part.
In a two-part mold, which is often used in a sand casting, the upper half, including the top half of the flask, is called a “cope” and the lower half is called a “drag.” A parting surface may separate the cope and drag. The drag is first filled partially with sand, and the pattern is placed near the parting surface. The cope is then assembled to the drag. A gating system, for introducing liquid molten metal into the mold cavity, is placed on the cope, and sand is poured on the cope half covering the pattern and the gating system. The sand is then compacted by vibration or other mechanical means, after which the pattern is extracted from the drag by opening the cope. The impression of the pattern on the sand forms the mold cavity. One or more cores may then be placed in the mold cavity to define features, such as internal passages, in a cast part.
The gating system extends from the mold cavity to an outer surface of the cope and allows molten metal to be poured into the mold cavity. At the outer surface of the cope, the gating system may include a pouring cup into which the molten metal is poured. The pouring cup may be fluidly connected to the mold cavity by one or more vertical sections called sprues, and one or more horizontal sections called runners. The molten metal flows from the pouring cup into different sections of the mold cavity through the sprues and the runners. As the molten metal in the mold cavity solidifies, it shrinks, thereby creating voids in the mold cavity that require more molten metal to fill. These voids are often referred to as “shrink defects.” A concept called “directional solidification” may be used in attempt to minimize shrink defects during solidification of the part. Implementing directional solidification concepts may include using one or more “risers” coupled to the gating system. These risers act as reservoirs of molten metal that provide additional material to fill shrink voids. As the molten metal in the mold cavity solidifies, the interface between the molten and the solid metal moves from the region where solidification began toward the risers. After all of the molten metal in the mold cavity solidifies, thereby forming the desired part, the cope is separated from the drag, and the part is extracted by breaking the sand surrounding the part. Any sand cores in the part may then be removed to open internal cavities of the part.
Although sand casting has many advantages, it is desirable to increase the yield of sand casting processes and improve surface finish and microstructure of parts produced by sand casting. Since the mold cavity and cores are made of compressed sand, sand-cast parts typically exhibit poor surface finish and dimensional accuracy. The use of sprues and runners to direct molten metal to different parts of the mold cavity may adversely affect the yield of sand casting processes and the quality of sand-cast parts. Since gravitation force drives the molten metal through the gating system, the time taken to fill the mold cavity may be high. Additionally, the temperature of the molten metal may drop while flowing through the gating system. If the molten metal cools to the metal-solidification temperature in the gating system, incomplete filling of the mold cavity may result. Thus, it is traditional to pour molten metal into the pouring cup at a higher temperature to prevent solidification of the metal in the gating system. Pouring the molten metal at such a high temperature, however, may result in a flow that is somewhat turbulent. Accordingly, with the molten metal poured at such a high temperature, heat may be readily transferred to the sand walls of the mold, causing the sand particles to fracture and therefore produce a poor surface finish on the metal casting. High pouring temperature may also produce poorer microstructure in the portions of the part that solidify last.
U.S. Pat. No. 5,503,214 issued to Cribley et al. (the '214 patent) describes a sand casting process in which the gating system eliminates runners. In the gating system of the '214 patent, a pouring cup is fluidly coupled to a mold cavity through a vertical down sprue. Molten metal, poured into the pouring cup, is delivered to the mold cavity through the vertical down sprue. A sand core, placed in the mold cavity, defines the shape of a disk rotor that may be cast using the sand casting process of the '214 patent. When the mold is fully assembled, the down sprue connects to a flow passage extending through the core in the mold cavity. A filter element placed in the flow path of the '214 patent, filters particulates from the molten metal and provides a flow-constricting gap, to slow the flow of molten metal into the mold cavity. The down sprue also serves as a riser to provide a reservoir of molten metal to fill voids formed during shrinkage. By eliminating runners the method of the '214 patent may eliminate some deficiencies associated with typical sand casting processes (discussed earlier). However, the sand casting process of the '214 patent may have drawbacks. For instance, the use of a sand core may result in poor dimensional accuracy and surface finish of the cast part. Additionally, the down sprue of the '214 patent may restrict the flow of molten metal into the mold cavity, thereby increasing the time taken to fill the mold cavity. As discussed above, restriction of the molten metal flow into the mold cavity may increase the temperature drop of the molten metal in the gating system, negatively impact directional solidification, and increase the formation of shrink defects.
In one aspect, a mold assembly for sand casting is disclosed. The mold assembly includes a drag having a first vertical axis and a first surface. The first surface extends generally perpendicular to the first vertical axis. The mold assembly also includes a cope having a second vertical axis positioned on the first surface such that the first vertical axis and the second vertical axis coincide to form a central vertical axis. The cope includes a second surface and a third surface both extending generally perpendicular to the second vertical axis. The mold assembly also includes a casting cavity disposed about the central vertical axis and located between the first surface and the second surface, and a core disposed about the central vertical axis and positioned in the casting cavity. The mold cavity further includes a pouring cup disposed about the second vertical axis and extending downward from the third surface to the casting cavity. The pouring cup is configured to deliver a substantial portion of liquid material at a time directly into the casting cavity without directing the liquid material through a choke point.
In another aspect, a method of sand casting a part is disclosed. The method includes forming a casting cavity between a cope and a drag of a molding assembly such that the casting cavity is located about a vertical axis of the molding assembly. The method also includes directing a substantial portion of liquid material at a time directly into casting cavity without directing the liquid material through a choke point. The method further includes shaping the liquid material in the casting cavity using a ceramic core, and solidifying the liquid material in the casting cavity to form a casting having a shape substantially resembling the part.
In yet another aspect, a method of creating a mold for sand casting a part is disclosed. The method includes forming a casting cavity between packed aggregate material of a cope and packed aggregate material of a drag. The cope and the drag being parts of a molding assembly having a central vertical axis, and the casting cavity is disposed about the central vertical axis. The method also includes locating a pouring cup on the cope. The pouring cup is shaped substantially like a frustum of a cone and is configured to deliver a substantial portion of a molten liquid at a time to the casting cavity without directing the molten liquid through a choke point. The method further includes positioning a ceramic core in the casting cavity such that the core is circumferentially disposed about the central vertical axis, the core being shaped such that a free space in the casting cavity not occupied by the core substantially resembles a shape of the cast part.
Cope 14 and drag 16 may each include a casing (cope casing 14A and drag casing 16A) containing an aggregate material (cope aggregate 14B and drag aggregate 16B), such as, for example sand. Cope casing 14A and drag casing 16A may be made of any material, such as, for example, wood, steel, etc. One or both of cope casing 14A and drag casing 16A may include handles or other similar features (not shown) configured to enable an operator to lift the casing. As can be seen in
As can be seen in
Mold assembly 10 may also have a flow path 31 extending from a top surface 22C of cope 14 to casting cavity 18. Flow path 31 may include a pouring cup 28 extending through cope aggregate 14B and fluidly communicating top surface 22C of cope 14 with bottom surface 22A. In some embodiments, pouring cup 28 may extend from top surface 22C to upper cavity wall 24A of cope print 18A. Pouring cup 28 may include a shell 28A that defines a vertical cavity 28B through cope aggregate 14B. Shell 28A may be made of any material, such as, for example, steel, ceramic, etc. In some embodiments, shell 28A may be eliminated and pouring cup 28 may consist of vertical cavity 28B defined through cope aggregate 14B. Pouring cup 28 may be circumferentially disposed about first vertical axis 88A and may be centrally positioned relative to cope print 18A. As seen in
Flow path 31 may be configured to deliver a substantial portion of liquid material at a time directly into casting cavity 18 without directing the liquid material through any choke points. In some embodiments, pouring cup 28 may be configured to deliver the liquid material directly into casting cavity 18 without presenting any choke points in the flow path 31. Delivering a substantial portion of liquid material at a time directly into casting cavity 18 (as opposed to directing a trickle of liquid material into casting cavity 18) may fill casting cavity 18 quickly. A choke point may be a geometric feature that disrupts a steady and continuous flow of the liquid material into casting cavity 18. In other words, a choke point may be a location in flow path 31 that may inhibit, or offer resistance to, the flow of liquid material into casting cavity 18. When a choke point is present in flow path 31, liquid material poured into pouring cup 28 may accumulate in pouring cup before (or while) filling casting cavity 18. In contradistinction, when liquid material is poured into flow path 31 without any choke points, the liquid material may fill casting cavity 18 before collecting in pouring cup 28 (or another component that fluidly couples pouring cup 28 to casting cavity 18). To illustrate typical choke points that may be present in a flow path 31, a few non-limiting examples will now be described. In a typical sand casting gating system, a location where a sprue connects to a pouring cup may act as a choke point due to the abrupt change in cross-sectional dimensions of the flow path. A filter element in flow path 31 may also act as a choke point by restricting the flow of liquid material into the casting cavity 18.
If flow path 31 included any choke points, some of the liquid material may collect in flow path 31 (before proceeding to casting cavity 18), thereby slowing the flow of liquid material into casting cavity 18. It is contemplated that, if flow path 31 is aligned about an axis (as in
Pouring cup 28 may also be configured to act as riser during the casting process. That is, after filling casting cavity 18, additional liquid material may accumulate in pouring cup 28. This reservoir of liquid material accumulated in pouring cup 28, may subsequently flow into casting cavity 18 to fill voids created when the liquid material in casting cavity 18 solidifies.
In the embodiment of mold assembly 10 depicted in
A casting core 30 may be disposed in casting cavity 18. The core 30 may be designed to shape the liquid material delivered to casting cavity 18. Core 30 may include passageways and/or other geometries to impart a desired shape to the liquid material in casting cavity 18. When the liquid material in casting cavity 18 solidifies, the resulting part formed of the solidified material (hereinafter “cast part” 50) may retain the shape imparted by core 30. As an illustrative example,
As best seen in
Core 30 may be constructed of various materials. For example, core 30 may typically be made of a refractory material. In some embodiments, core 30 may be made of a ceramic material and have a smooth surface finish. In this disclosure, the term smooth is used to refer to a surface finish that is substantially non grainy. A core made of pressed sand or other aggregate material may exhibit a rough or a grainy surface finish, while a core made of a ceramic material may exhibit a smooth, polished or a non grainy surface finish. The smooth surface finish of core 30 may translate to reduced surface roughness of a part cast in casting cavity 18.
To dispose core 30 in casting cavity 18, core 30 may be placed in drag print 18B with second end 30B proximate lower cavity wall 24B. In some embodiments, core 30 and drag print 18B may be dimensioned such that core 30 may have an interference fit with drag print 18B. Additionally, in some embodiments, when core 30 is placed in drag print 18B, third vertical axis 88C may substantially coincide with second vertical axis 88B. In some embodiments, core 30 may be placed in drag print 18B such that second end 30B of core 30 may touch lower cavity wall 24B. For example, to form an open faced impeller in mold assembly 10, a suitable core may be placed in drag print 18B such that the core is flush with lower cavity wall 24B.
With the core 30 placed in drag print 18B, the mold assembly 10 may be closed. That is, cope 14 may be placed over drag 16. In the closed configuration, locating features 26A-26F on cope 14 and drag 16 may align cope print 18A and drag print 18B to form casting cavity 18 with core 30 disposed therein. As shown in
Liquid material, poured into casting cavity 18 through pouring cup 28, may fill free space 40, and solidify to form cast part 50. In some embodiments, the surface of core 30 may be smooth to impart a smooth surface finish to cast part 50. Additionally, in some embodiments, liquid material may include molten liquid metal. In such embodiments, solidification may occur when the molten liquid metal in free space 40 of cavity 18 cools. When the molten metal solidifies, the liquid material in passageways 32 may form blades 52, liquid material in cavity 34 may form flange 54A, liquid material in the space between first end 30A and upper cavity wall 24A may form base 54B, and the liquid material in the space between second end 30B and lower cavity wall 24B may form the shroud 60.
The disclosed embodiments relate to a sand casting process for making precision parts. The process includes using a pouring cup, attached to a cope of a mold assembly, to directly pour liquid material into a mold cavity of the mold assembly without directing the liquid material through a choke point. A ceramic core having a smooth surface finish is disposed within the mold cavity such that space in the mold cavity not occupied by the core substantially resembles the shape of the part to be cast. Pouring liquid material directly into the mold cavity without the use of sprues and runners enables the mold cavity to be filled quickly without a significant temperature drop of the liquid material during the pouring process, thereby favoring directional solidification of a cast part. The use of a ceramic core with a smooth surface finish also improves the surface finish of the cast part and allows casting the part with dimensions close to the desired final dimensions for the part. To illustrate the disclosed precision casting process, a method of casting an impeller will now be described.
Drag 16 of mold assembly 10 may be loosely filled with sand and a pattern (not shown) placed on top surface 22B thereof. The sand may include a binder or other chemicals that promote adhesion between the sand particles. The shape of the pattern may substantially resemble the shape of casting cavity 18. The pattern may be pressed into top surface 22B so as to create a depression resembling drag print 18B on the sand in drag 16. Cope 14 may now be placed on top surface 22B such that locating features 26B, 26D, and 26F on cope 14 mate with locating features 26A, 26C, and 26E on drag 16. In this configuration, first vertical axis 88A may coincide with second vertical axis 88B. Pouring cup 28, having a shape resembling a frustum of a cone, may be placed within cope 14 such that a longitudinal axis of pouring cup 28 coincides with first vertical axis 88A. Pouring cup 28 may be oriented in cope 14 such that a smaller diameter end of pouring cup 28 abuts the pattern placed on top surface 22B of drag 16, and an opposite larger diameter end of pouring cup 28 extends from top surface 22C of cope 14. Sand may now be poured into cope 14 around pouring cup 28 and compacted. Compaction of the sand in cope 14 may eliminate voids in the sand in cope 14 and drag 16, and tightly pack the sand around the pattern and pouring cup 28. Cope 14 may now be gently lifted off drag 16, and the pattern removed. Impression of the pattern on the sand in the cope 14 may create cope print 18A on bottom surface 22A, and impression of the pattern on sand in drag 16 may create drag print 18B on top surface 22B.
After creation of drag print 18B and separation of cope 14 from drag 16, core 30, made of a ceramic material, may be placed in drag print 18B. In this configuration, second end 30b of core 30 may be in a spaced relationship with lower cavity wall 24B of drag print 18B. Core 30 may be constructed such that outer surfaces of core 30 may have a smooth surface finish. After core 30 is placed in drag print 18B, cope 14 and drag 16 may be closed. In the closed configuration, cope print 18A may join with drag print 18B to form casting cavity 18 with core 30 located in therein. In this configuration, pouring cup 28 may provide a flow path 31 that fluidly communicates top surface 22C of cope 14 with casting cavity 18 (see
Molten liquid metal may be poured into casting cavity 18 through the flow path 31 provided by pouring cup 28. The liquid metal may fill free space 40 in casting cavity 18. In some embodiments, the amount of molten metal poured into pouring cup 28 may be such that a reserve of molten metal remains in pouring cup 28 after the molten metal has filled free space 40 in casting cavity 18. As the temperature of the molten metal in casting cavity 18 decreases, the molten metal may solidify. The shape of pouring cup 28 and free space 40 may favor the solidification of molten metal in contact with lower cavity wall 24B first. As the metal solidifies, the metal shrinks, creating voids (shrink voids), and liquid metal from surrounding regions move in to fill these voids. The reserve of liquid metal in pouring cup 28 may replace the liquid metal in casting cavity 18 used to fill the shrink voids, thereby keeping casting cavity 18 full of metal during the solidification process. Solidification of liquid metal may thus proceed from the lower cavity wall 24B towards the reserve of molten metal in pouring cup 28.
After the liquid metal in casting cavity 18 solidifies, cope 14 may be separated from drag 16, and the solidified cast part 50 removed from casting cavity 18. In some cases, cast part 50 along with core 30 may be taken from the casting cavity 18, and core 30 broken away from cast part 50. The surface of cast part 50 in contact with core 30 may have a smooth surface finish due to the smooth surface finish of core 30. Machining and/or other material-removal operations may be carried out to give the cast part 50 its desired final shape and dimensions. The material-removal operations may include machining a through-hole 56 through flange 54A of cast part 50.
The use of a ceramic core while casting the impeller may reduce post-casting machining operations needed to finish the impeller to desired dimensions. The smooth surface finish of the core may also improve the surface finish of the surfaces of the impeller in contact with the core. This improved surface finish may reduce, or eliminate, the need for polishing operations for polishing the surfaces of blades 52 in passageways 58 of the impeller.
Elimination of sprues and runners from the gating system of the mold assembly allows the molten liquid to be poured directly into the casting cavity without creating a choke point in flow path 31. Pouring the molten liquid directly into the casting cavity allows the casting cavity to be filled quickly without an appreciable drop in temperature of the molten liquid. Limiting the temperature drop of the molten liquid during the pouring process enhances directional solidification of the molten liquid in the casting cavity and decreases the formation of shrink defects.
It will be apparent to those skilled in the art that various modifications and variations can be made to the disclosed precision casting process. Other embodiments will be apparent to those skilled in the art from consideration of the specification and practice of the disclosed precision casting process. It is intended that the specification and examples be considered as exemplary only, with a true scope being indicated by the following claims and their equivalents.
