The present invention relates to the cooling of molten metal in a mold with a bath which is at a lower temperature than the molten metal in the mold.
It has previously been suggested that a casting apparatus may employ either a body of molten metal or a fluidized bed as a cooling bath to promote directional solidification of an article in a mold. Apparatus for doing this is disclosed in U.S. Pat. No. 6,308,767 and in U.S. Pat. No. 6,776,213. When a mold is immersed in a body of molten metal or a fluidized bed, there is a tendency for the mold to move relative to a support on which the mold is disposed.
The present invention relates to a new and improved method and apparatus for use in casting metal articles. A mold is positioned on a support with an anchor extending upward from the support into the mold. The mold and the anchor are interconnected by a retainer member which extends through a portion of the mold into the anchor.
The mold is at least partially filled with molten metal while the mold is disposed on the support. Thereafter, the mold is at least partially immersed in a bath. Force is transmitted between the mold and the anchor to retain the mold against movement relative to the support during performance of the step of immersing the mold in a bath. The bath may be formed in any desired manner.
The present invention has a plurality of different features which are advantageously utilized together in the manner described herein. However, it is contemplated that the features may be utilized separately and/or in combination with features from the prior art.
The foregoing and other features of the invention will become more apparent upon a consideration of the following description taken in connection with the accompanying drawings wherein:
An improved casting apparatus 10 is illustrated schematically in
The casting apparatus 10 is enclosed by a suitable housing (not shown) which is connected with a source of vacuum or low pressure by conduits. The housing enables an evacuated atmosphere to be maintained around the furnace assembly 16 and container 20 holding the body 22 of molten metal. The housing may have any one of many known constructions, including the construction disclosed in U.S. Pat. No. 6,776,213 and/or the construction shown in U.S. Pat. No. 6,308,767. Of course, the housing may have a construction which is different than the known constructions illustrated in the aforementioned patents.
A framework 26 (
If desired, the mold support 32 may have the same construction as is disclosed in my co-pending U.S. patent application entitled “Method of Casting Metal Articles” (Attorney Docket No. PCC-8902). The disclosure in the aforementioned U.S. patent application (Attorney Docket No. PCC-8902) is hereby incorporated herein in its entirety by this reference thereto. Alternatively, the mold support 32 may have a circular disk shaped construction.
A lower drive assembly 38 is connected with the container 20 which holds the body 22 of molten metal. The lower drive assembly 38 is operable to raise and lower the container 20 relative to the furnace assembly 16. The upper and lower drive assemblies 34 and 38 may be operated simultaneously and/or sequentially to raise and/or lower the framework 26 and/or container 20 holding the body 22 of molten metal.
During operation of the casting apparatus 10, the one piece ceramic mold structure 12 is supported in the furnace assembly 16 by the framework 26. The mold structure is disposed on the mold support 32 forming the base of the framework 26. The mold structure 12 may have any desired construction and be utilized to cast any desired article. The illustrated mold structure 12 is utilized to cast turbine engine components.
Heat is transmitted from the mold structure to the metal support 32 which functions as a chill plate. The mold structure 12 is raised and lowered relative to the furnace assembly 16 by operation of the upper drive assembly 34 which is connected to the support structure 32. If desired, a flow of cooling liquid may be conducted through the framework 26 and/or mold support 32. It is contemplated that the framework 26 may be constructed so as to be located outside of the furnace assembly 16.
While the mold structure 12 is supported in the furnace assembly 16 on the framework 26, in the manner listed schematically in
With the exception of the plug 52, the illustrated mold structure 12 is of a one-piece ceramic construction. However, the mold structure 12 may be formed by two or more pieces and may have a construction other than a ceramic construction.
The mold structure 12 has a construction which is generally similar to the construction disclosed in U.S. Pat. Nos. 5,048,591; 5,062,468; and/or 5,072,771. The mold structure 12 is utilized to cast turbine engine components. However, it should be understood that the mold structure 12 may have a construction which is different than the construction which is disclosed in the aforementioned patents and/or may be used to cast articles other than turbine engine components.
The mold structure 12 is filled with molten metal while the mold structure is in the furnace assembly 16. The molten metal with which the mold structure is filled is a molten nickel-chrome super alloy which melts at a temperature which is greater than 3,000 degrees Fahrenheit. Of course, the mold structure may be filled with a different molten metal which melts at a different temperature. For example, the mold structure 12 may be filled with molten titanium or a titanium alloy.
Once the mold structure 12 has been filled with the molten nickel-chrome super alloy or other metal, the upper drive assembly 34 is operated to lower the framework and mold structure 12 into the body 22 of a second molten metal in the container 20. While the upper drive assembly 34 is operated to lower the mold structure 12, the lower drive assembly 38 may be operated to raise the body 22 of liquid metal. It should be understood that the mold structure 12 may be immersed in the body 22 of molten metal by lowering the support structure 32 without raising the body 22 of molten metal. Alternatively, the furnace assembly may be raised relative to the mold structure 12 and the body 22 of molten metal raised relative to the mold structure to immerse the mold structure in the body of molten metal. Although either one of the mold structure 12 and body 22 of molten metal may be moved relative to the other to effect immersion of the mold structure 12 in the body 22 of molten metal, it may be desired to both raise the body 22 of molten metal and lower the mold structure 12.
The molten super alloy in the mold structure 12 is at a temperature above 3,000 degrees Fahrenheit. The body 22 of molten metal is at a temperature below 1,000 degrees Fahrenheit. The resulting temperature differential between the molten metal in the mold structure 12 and the molten metal in the body 22 of molten metal results in directional solidification of the molten metal in the mold structure 12 as the mold structure is immersed in the body of molten metal. The molten metal in the mold structure 12 may solidify with either a columnar grain crystallographic structure or with a single crystal crystallographic structure.
In the illustrated embodiment of the invention, the body 22 of molten metal is formed of tin and is at a temperature of approximately 500 degrees Fahrenheit. However, the body 22 of molten metal may be formed of lead or aluminum if desired. The molten metal in the mold structure is a nickel-chrome super alloy with a melting temperature which may be approximately 3,700 degrees Fahrenheit. Of course, a different molten metal may be poured into the mold structure 12. It is also contemplated that the body 22 of molten metal may be replaced by a fluidized bed, in the manner disclosed in the aforementioned U.S. Pat. No. 6,776,213.
It should be understood that the specific temperatures for the body 22 of molten metal and the molten metal in the mold structure 12 will vary depending upon the composition of the metal. For example, the body 22 of molten metal may be any one of many metals which is liquid (molten) at a temperature below 1,500 degrees Fahrenheit. The molten metal in the mold structure 12 may be any one of many different metals which melt at a temperature above 2,000 degrees Fahrenheit.
The greater the temperature differential between the temperature of the molten metal in the mold structure 12 and the body 22 of molten metal, the greater will be the rate in which heat is withdrawn from the molten metal in the mold structure as the mold structure is immersed in the body 22 of molten metal. Of course, the rate of heat transfer from the molten metal in the mold structure 12 to the body 22 of molten metal will also vary as a function of the rate at which the mold structure and body of molten metal are moved relative to each other by the upper and/or lower drive assemblies 34 and 38.
A layer 60 of insulating material is provided above the body 22 of molten metal. The layer 60 of insulating material forms a baffle to block heat transfer to the body 22 of molten metal. Although the baffle provided by the layer 60 of insulating material facilitates maintaining a relatively large temperature differential between the furnace assembly 16 and the body 22 of molten metal, the layer of insulating material may be eliminated if desired.
The layer 60 of insulating material floats on the upper surface 62 of the body 22 of molten metal. The layer of insulating material shields the body 22 of molten metal from the relatively hot environment of the furnace assembly 16. Thus, the layer 60 of insulating material retards heat transfer from the furnace assembly 16 and mold structure 12 to the body 22 of molten metal. This enables the body 22 of molten metal to be maintained at a relatively low temperature during preheating of the mold structure and during pouring of molten metal into the mold structure.
The layer 60 of insulating material may be formed of many different materials. In the illustrated embodiment of the invention, the layer 60 of insulating material is formed of refractory particles which float on the body 22 of molten metal. However, it is contemplated that the layer 60 of insulating material may be formed in a different manner if desired. For example, the layer 60 of insulating material may be formed by hollow members which have a construction similar to any one of the constructions disclosed in U.S. Pat. Nos. 6,446,700 and 6,035,924.
If desired, the layer 60 of insulating material may be disposed above and spaced from the body 22 of molten metal. At least a portion of the layer 60 of insulating material may have a relatively rigid construction and have one or more openings which the mold structure 12 and mold support 32 move. If this is done, the layer 60 of insulating material may be connected with the upper end portion of the container 20.
In the embodiment of the invention illustrated in
In accordance with a feature of the present invention, an anchor 80 (
As the mold structure 12 is immersed in the body 22 of molten metal, force is transmitted between the mold structure 12 and the anchor 80 to retain the mold structure against movement relative to the mold support 32. In addition, force is transmitted between the retainer member 84 and both the mold structure 12 and anchor 80 to further retain the mold structure 12 against movement relative to the mold support 32.
In the illustrated embodiment of the invention, the mold support 32 has a circular configuration. The base plate 50 of the mold structure 12 also has a circular configuration. The article molds 44 are disposed in a circular array about the downpole 48 of the mold structure 12. The downpole 48 is disposed in a central portion of the circular array of article molds 44. It should be understood that the mold support 32 and/or mold structure 12 may have a configuration which is different than the configuration illustrated herein.
The mold support 32, mold structure 12, and downpole 48 have a common central axis 92 (
However, it is contemplated that the anchor 80 may be offset to one side of the downpole 48 and the central axis 92 of the mold structure 12. If this is done, the mold structure 12 would be constructed so as to provide a socket at a location offset from the central axis 92 to receive the anchor 80. Although the socket would be offset from the central axis 92 of the mold structure 12 and support 32, the socket may be located in the central portion of the circular array of article molds 44. Alternatively, the socket may be located radially outwardly of the circular array of article molds 44. If desired, the downpole 48 may be eliminated.
The retainer member 84 extends through an opening 98 in the anchor 80 (
The retainer member 84 has a central axis 106 (
In the embodiment of the invention illustrated in
The illustrated anchor 80 extends only partway along the length of the downpole 48. If desired, the anchor may be constructed so as to extend upward to the plug 52 (
The anchor 80 is formed of a heat resistant material which can withstand the relatively high heats to which the mold structure 12 is subjected during preheating of the mold structure and pouring of molten metal into the mold structure. In the specific embodiment of the invention illustrated in FIG. 1, the anchor 80 is formed of graphite. However, it is contemplated that the anchor 80 may be formed of a different material if desired. For example, the anchor 80 may be formed of a suitable ceramic material. If the plug 52 is omitted, the anchor 80 may be formed of a ceramic material and have an upper surface which forms the bottom of the pour cup 42.
The retainer member 84 transmits force between the anchor 80 and mold structure 12 to retain the mold structure against vertical movement relative to both the anchor 80 and mold support 32. The illustrated retainer member 84 has a cylindrical configuration and is formed as a pin which extends through both the downpole 48 and the anchor 80. However, the retainer member 84 may be formed of a length such that it extends only partway through both the downpole 48 and the anchor 80.
The illustrated retainer member 84 has a cylindrical configuration. However, the retainer member 84 may have a different configuration if desired. For example, the retainer member 84 may be formed with a polygonal cross sectional configuration. The illustrated retainer member 84 is formed of stainless steel. However, the retainer member 84 may be formed of a suitable heat resistant material, such as a ceramic material.
It is contemplated that the retainer member 84 may be formed with a head end portion which extends radially outward from the cylindrical body of the retainer member 84. The head end portion of the retainer member 84 would engage the outer side surface of the cylindrical downpole 48 to position the retainer member axially relative to both the anchor 80 and downpole. Alternatively, the opening 98 may extend part way through the anchor 80. This would enable the retainer member 84 to be positioned axially relative to the anchor 80 and downpole 48 by engagement with an end surface of the opening 98.
The mold structure 12 and mold support 32 are interconnected by the anchor 80 and retainer member 84. Prior to positioning of the mold structure 12 on the support 32, the anchor 80 is secured to the support 32 by the fastener 88 (
Prior to lowering of the mold structure 12 onto the support 32, the mold structure is positioned relative to the support with the longitudinal central axis 92 of the mold structure aligned with the longitudinal central axis of the anchor 80. As the mold structure 12 is lowered onto a support 32, the anchor 80 is telescopically inserted into the socket formed by the central opening 94 in the downpole 48. As this occurs, a bottom surface on the base plate 50 of the mold structure 12 engages the upper surface 110 of the mold support 32.
As the mold structure 12 is positioned on the mold support 32 (
When the support 32 and mold structure 12 are lowered into the body 22 of molten metal, the anchor 80 and retainer member 84 cooperate to hold the mold structure against movement relative to the mold support 32. Thus, sideward forces applied to the mold structure 12 are transmitted through the cylindrical inner side surface of the downpole 48 directly to the anchor 80. In addition, any upward forces applied against the mold structure 12 are transmitted to the anchor 80 through the retainer member 84. This results in the mold structure 12 being held against both sideward and upward movement relative to the mold support 32 as the mold structure is immersed in the body 22 of molten metal. Forces applied to the anchor 80 are transmitted to the mold support 32 by the fastener 88.
In the embodiment of the invention illustrated in
A casting apparatus 10a (
The mold structure 12a (
The mold structure 12a includes a plurality of article molds 44a which extend upwardly from a base plate 50a of the mold structure 12a. The article molds 44a are disposed in a circular array. The base plate 50a is integrally formed as one piece with the article molds 44a. The mold 12a does not have a downpole corresponding to the downpole 48 of
In accordance with a feature of the embodiment of the invention illustrated in
The anchors 80a are offset to one side of the central axis 92a of the mold structure. If desired, one of the anchors 80a may be aligned with the central axis 92a of the mold structure 12a. If the mold structure 12a is to be provided with a downpole, the anchors 80a would be offset from the downpole and disposed within the circular array of article molds 44a.
The mold structure 12a includes anchor housings 130 which are integrally formed as one piece with the base plate 50a. The mold housings 130 define cylindrical sockets 132 in which the cylindrical anchors 80a are telescopically received. The anchor housings 130 are disposed within the circular array of article molds 44a. However, one or more of the anchor housings 130 may be disposed radially outward of the circular array of article molds 44a.
The retainer members 84a have a cylindrical configuration with longitudinal central axes which extend parallel to an upper side surface 110a of the mold support 32a and perpendicular to central axes of the anchors 80a and to the central axis 92a of the mold structure 12a. The retainer members 84a extend through portions of the mold structure, that is, the anchor housings 130, and through the anchors 80a.
The present invention relates to a new and improved method and apparatus for use in casting metal articles. A mold 12 is positioned on a support 32 with an anchor 80 extending upward from the support into the mold. The mold 12 and the anchor 80 are interconnected by a retainer member 84 which extends through a portion of the mold 12 into the anchor 80.
The mold 12 is at least partially filled with molten metal while the mold is disposed on the support 32. The mold 12 is at least partially immersed in a bath 22. Force is transmitted between the mold 12 and the anchor 80 to retain the mold against movement relative to the support during performance of the step of immersing the mold in the bath 22. The bath 22 may be formed in any desired manner. For example, the bath 22 may be formed by either a body of molten metal or fluidized bed.
The present invention has a plurality of different features which are advantageously utilized together in the manner described herein. However, it is contemplated that the features may be utilized separately and/or in combination with features from the prior art.
This application is a continuation of U.S. patent application Ser. No. 12/145,076 filed Jun. 24, 2008. The benefit of the earlier filing date of the aforementioned application Ser. No. 12/145,076 is hereby claimed. The disclosure in the aforementioned application Ser. No. 12/145,076 is hereby incorporated herein in its entirety by this reference thereto.
Number | Date | Country | |
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Parent | 12145076 | Jun 2008 | US |
Child | 12768256 | US |