Claims
- 1. A holder furnace, comprising:a storage vessel having sidewalls and a bottom wall defining a molten metal receiving chamber for containing a supply of molten metal; at least one furnace insulating layer lining the molten metal receiving chamber of the storage vessel; a thermally conductive heat exchanger block located at the bottom of the molten metal receiving chamber for heating the supply of molten metal, with the heat exchanger block having a top face, a bottom face, and side faces, and with the heat exchanger block having a plurality of electrical heaters each including a continuous electrically resistive heating element extending therein and projecting outward from at least one of the faces of the heat exchanger block and further extending through the furnace insulating layer and at least one of the sidewalls of the storage vessel for connection to a source of electrical power; and a sealing layer covering the bottom face and side faces of the heat exchanger block and completely lining the molten metal receiving chamber such that the heat exchanger block is substantially separated from contact with the furnace insulating layer, and such that the molten metal from the supply of molten metal is prevented from contacting the electrical heaters, wherein the heating element of each of the electrical heaters, in operation, generates heat energy that is transferred to the heat exchanger block for heating the molten metal in the molten metal receiving chamber.
- 2. The holder furnace of claim 1, wherein the heat exchanger block includes a plurality of individual heat exchanger blocks connected together along side faces by a tongue-in-groove connection.
- 3. The holder furnace of claim 1, wherein the storage vessel further includes a molten metal inlet for receiving the supply of molten metal into the molten metal receiving chamber from an external source, and a molten metal outlet for returning the supply of molten metal to the external source.
- 4. The holder furnace of claim 3, further comprising a layer of refractory material located within the molten metal receiving chamber and on top of the heat exchanger block, with the layer of refractory material defining a plurality of vertically extending chambers, and wherein the sealing layer further partially covers the top face of the heat exchanger block such that the top face of the heat exchanger block is separated from contact with the layer of refractory material except on areas of the top face substantially coincident with the vertically extending chambers.
- 5. The holder furnace of claim 4, wherein the plurality of vertically extending chambers is connected in series from the molten metal inlet to the molten metal outlet of the storage vessel.
- 6. The holder furnace of claim 4, further comprising a cover positioned on top of the storage vessel and substantially enclosing the molten metal receiving chamber, and wherein the cover defines a plurality of openings corresponding to the plurality of vertically extending chambers for receiving, respectively, a plurality of molten metal injectors into the plurality of vertically extending chambers.
- 7. The holder furnace of claim 1, wherein the sealing layer further lines the molten metal receiving chamber, and wherein the at least one furnace insulating layer includes a plurality of furnace insulating layers positioned between the sealing layer and the sidewalls and bottom wall of the storage vessel.
- 8. The holder furnace of claim 1, wherein the sealing layer comprises an alumina fiber mat.
- 9. The holder furnace of claim 1, wherein the heat exchanger block is made of one of graphite and silicon carbide.
- 10. The holder furnace of claim 1, wherein the electrical heaters extend between opposite sidewalls of the storage vessel and through the heat exchanger block, wherein the continuous heating element of each of the electrical heaters extends through at least one of the opposite sidewalls, the at least one furnace insulating layer, and extends at least partially through the heat exchanger block, and wherein the electrical heaters each further include respective tubes extending through the opposite sidewalls, the at least one furnace insulating layer, and extending at least partially into opposite faces of the heat exchanger block, with the heating element of each of the electrical heaters extending at least partially through the tubes, respectively.
- 11. The holder furnace of claim 10, further including sealing gaskets positioned within the heat exchanger block, and wherein the sealing gaskets cooperate, respectively, with ends of the tubes extending into the opposite faces of the heat exchanger block for preventing molten metal from leaking into the tubes and contacting the heating element of the electrical heaters.
- 12. The holder furnace of claim 11, wherein the tubes are ceramic insulating tubes and are each surrounded by a layer of ceramic fiber rope for preventing molten metal from the supply of molten metal from leaking into the ceramic insulating tubes and contacting the heating element of the electrical heaters.
- 13. The holder furnace of claim 12, further including flange plates attached, respectively, to the ceramic insulating tubes at the opposite sidewalls of the storage vessel, and wherein the ceramic insulating tubes are held in compression against the opposite sidewalls of the storage vessel by the flange plates and mechanical fasteners.
- 14. The holder furnace of claim 10, further comprising a source of inert gas in fluid communication with the heat exchanger block through the tubes such that the heating element of the electrical heaters operates substantially in an inert gas atmosphere during operation of the holder furnace.
- 15. A heat exchanger block for use in combination with a holder furnace comprising a storage vessel defining a molten metal receiving chamber lined with at least one furnace insulating layer and a sealing layer completely lining the molten metal receiving chamber, the heat exchanger block comprising:a thermally conductive block having a top face, bottom face, and side faces; a plurality of continuous electrically resistive heating elements extending into the thermally conductive block and including a portion projecting outward from one of the side faces of the thermally conductive block; a first plurality of tubes positioned, respectively, about the portion of the heating elements projecting outward from the thermally conductive block, with the first plurality of tubes extending at least partially into the thermally conductive block; and a first plurality of sealing gaskets located within the thermally conductive block and positioned, respectively, adjacent ends of the first plurality of tubes extending into the thermally conductive block, with the sealing gaskets cooperating with the ends of the first plurality of tubes for preventing molten metal from contacting the heating elements when the heat exchanger block is used in the holder furnace, wherein the heating elements, in operation, generate heat energy that is transferred to the thermally conductive block for heating the molten metal in the holder furnace, and wherein with the heat exchanger block positioned in the molten metal receiving chamber, the sealing layer covers the bottom face and side faces of the thermally conductive block such that the thermally conductive block is substantially separated from contact with the at least one furnace insulating layer, and such that molten metal received in the molten metal receiving chamber is prevented from contacting the heating elements.
- 16. The heat exchanger block of claim 15, wherein the heating elements extend through the thermally conductive block substantially to an opposite side face of the thermally conductive block, with the heating elements each having an end terminating within the thermally conductive block, and with the heat exchanger block further including:a second plurality of tubes extending at least partially into the opposite side face of the thermally conductive block and cooperating, respectively, with the ends of the heating elements located within the thermally conductive block; and a second plurality of sealing gaskets located within the thermally conductive block and positioned, respectively, adjacent ends of the second plurality of tubes extending into the thermally conductive block at the opposite side face, with the sealing gaskets cooperating with the ends of the second plurality of tubes extending into the thermally conductive block at the opposite side face for preventing molten metal from contacting the heating elements when the heat exchanger block is used in the holder furnace.
- 17. The heat exchanger block of claim 16, wherein the first and second plurality of tubes are ceramic insulating tubes, and wherein exposed portions of the first and second plurality of ceramic insulating tubes extending outward from the side faces of the thermally conductive block are surrounded by a layer of ceramic fiber rope for preventing molten metal from the holder furnace from leaking into the first and second plurality of ceramic insulating tubes and contacting the heating elements when the heat exchanger block is used in the holder furnace.
- 18. The heat exchanger block of claim 15, further including a sealing layer covering the bottom face and side faces of the thermally conductive block, with the sealing layer comprising an alumina fiber mat.
- 19. The heat exchanger block of claim 15, wherein the thermally conductive block is made of one of graphite and silicon carbide.
- 20. A molten metal casting system, comprising:a casting mold defining a mold cavity for casting a metal component; a plurality of molten metal injectors supported from a bottom side of the casting mold and in fluid communication with the mold cavity; a holder furnace located below the casting mold and molten metal injectors for containing a supply of molten metal for injection into the mold cavity through the molten metal injectors, with the holder furnace further comprising: a storage vessel having sidewalls and a bottom wall defining a molten metal receiving chamber for containing the supply of molten metal; at least one furnace insulating layer lining the molten metal receiving chamber of the storage vessel; a thermally conductive heat exchanger block located at the bottom of the molten metal receiving chamber for heating the supply of molten metal, with the heat exchanger block having a top face, a bottom face, and side faces, and with the heat exchanger block having a plurality of electrical heaters each including a continuous electrically resistive heating element extending therein and projecting outward from at least one of the faces of the heat exchanger block and further extending through the furnace insulating layer and at least one of the sidewalls of the storage vessel for connection to a source of electrical power; and a sealing layer covering the bottom face and side faces of the heat exchanger block and completely lining the molten metal receiving chamber such that the heat exchanger block is substantially separated from contact with the furnace insulating layer, and such that the molten metal from the supply of molten metal is prevented from contacting the electrical heaters; and a lift device located beneath the bottom wall of the storage vessel for lifting the holder furnace into engagement with the plurality of molten metal injectors such that the molten metal injectors extend into the molten metal receiving chamber, wherein the heating element of each of the electrical heaters, in operation, generates heat energy that is transferred to the heat exchanger block for heating the molten metal in the molten metal receiving chamber.
- 21. The molten metal casting system of claim 20, wherein the storage vessel further includes a molten metal inlet for receiving the supply of molten metal into the molten metal receiving chamber from an external source, and a molten metal outlet for returning the supply of molten metal to the external source.
- 22. The molten metal casting system of claim 21, further comprising a layer of refractory material located within the molten metal receiving chamber and on top of the heat exchanger block, with the layer of refractory material defining a plurality of vertically extending chambers, and wherein the sealing layer further partially covers the top face of the heat exchanger block such that the top face of the heat exchanger block is separated from contact with the layer of refractory material except on areas of the top face substantially coincident with the vertically extending chambers.
- 23. The molten metal casting system of claim 22, wherein the plurality of vertically extending chambers is connected in series from the molten metal inlet to the molten metal outlet of the storage vessel.
- 24. The molten metal casting system of claim 22, further comprising a cover positioned on top of the storage vessel and substantially enclosing the molten metal receiving chamber, and wherein the cover defines a plurality of openings corresponding to the plurality of vertically extending chambers for receiving, respectively, a plurality of molten metal injectors into the plurality of vertically extending chambers.
- 25. The molten metal casting system of claim 20, wherein the sealing layer comprises an alumina fiber mat.
- 26. The molten metal casting system of claim 20, wherein the electrical heaters extend between opposite sidewalls of the storage vessel and through the heat exchanger block, wherein the continuous heating element of each of the electrical heaters extends through at least one of the opposite sidewalls, the at least one furnace insulating layer, and extends at least partially through the heat exchanger block, and wherein the electrical heaters each further include respective tubes extending through the opposite sidewalls, the at least one furnace insulating layer, and extending at least partially into opposite faces of the heat exchanger block, with the heating element of each of the electrical heaters extending at least partially through the tubes, respectively.
- 27. The molten metal casting system of claim 26, further including sealing gaskets positioned within the heat exchanger block, and wherein the sealing gaskets cooperate, respectively, with ends of the tubes extending into the opposite faces of the heat exchanger block for preventing molten metal from leaking into the tubes and contacting the heating element of the electrical heaters.
- 28. The molten metal casting system of claim 27, wherein the tubes are ceramic insulating tubes and are each surrounded by a layer of ceramic fiber rope for preventing molten metal from the supply of molten metal from leaking into the ceramic insulating tubes and contacting the heating element of the electrical heaters.
- 29. The molten metal casting system of claim 28, further including flange plates attached, respectively, to the ceramic insulating tubes at the opposite sidewalls of the storage vessel, and wherein the ceramic insulating tubes are held in compression against the opposite sidewalls of the storage vessel by the flange plates and mechanical fasteners.
- 30. The molten metal casting system of claim 26, further comprising a source of inert gas in fluid communication with the heat exchanger block through the tubes such that the heating element of the electrical heaters operates
Government Interests
The subject matter of this application was made with United States government support under Contract No. 86X-SU545C awarded by the Department of Energy. The United States government has certain rights to this invention.
US Referenced Citations (17)
Foreign Referenced Citations (4)
Number |
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Oct 1992 |
EP |
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JP |
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