Molten metal holder furnace and casting system incorporating the molten metal holder furnace

Information

  • Patent Grant
  • 6516868
  • Patent Number
    6,516,868
  • Date Filed
    Thursday, January 25, 2001
    23 years ago
  • Date Issued
    Tuesday, February 11, 2003
    21 years ago
Abstract
A bottom heated holder furnace (12) for containing a supply of molten metal includes a storage vessel (30) having sidewalls (32) and a bottom wall (34) defining a molten metal receiving chamber (36). A furnace insulating layer (42) lines the molten metal receiving chamber (36). A thermally conductive heat exchanger block (54) is located at the bottom of the molten metal receiving chamber (36) for heating the supply of molten metal. The heat exchanger block (54) includes a bottom face (65), side faces (66), and a top face (67). The heat exchanger block (54) includes a plurality of electrical heaters (70) extending therein and projecting outward from at least one of the faces of the heat exchanger block (54), and further extending through the furnace insulating layer (42) and one of the sidewalls (32) of the storage vessel (30) for connection to a source of electrical power. A sealing layer (50) covers the bottom face (65) and side faces (66) of the heat exchanger block (54) such that the heat exchanger block (54) is substantially separated from contact with the furnace insulating layer (42).
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention relates to a holder furnace for containing a supply of molten metal and, more particularly, to a bottom heated holder furnace that may be used as part of a molten metal casting system.




2. Description of the Prior Art




Molten metal holding furnaces, or holder furnaces, are used in the art for holding and/or melting molten metal. Holding furnaces are often used to contain a supply of molten metal for injection into a casting machine. For example, U.S. Pat. No. 4,753,283 to Nakano discloses a horizontal injection casting machine in which molten metal is maintained in a holding furnace which periodically provides molten metal to the casting machine. Molten metal from a larger smelting furnace is supplied periodically to the holding furnace to maintain a set amount of molten metal in the holding furnace. The holding furnace is heated by a burner located adjacent a sidewall of the holding furnace.




In addition to the burner arrangement disclosed by the Nakano patent, several other methods are known in the art for heating molten metal contained in a holding furnace. Several common methods include induction heating, radiant heating, and immersion heating. For example, U.S. Pat. No. 4,299,268 to Lavanchy et al. discloses a molten metal casting arrangement in which molten metal is contained in a large capacity pressure ladle (i.e., holding furnace) that is heated by a heating inductor located at the bottom of the pressure ladle. The pressure ladle periodically supplies molten metal to a smaller capacity tilting ladle, which supplies molten metal to a casting apparatus. U.S. Pat. No. 3,991,263 to Folgero et al. discloses a similar molten metal holding system to that disclosed by the Lavanchy et al. patent, but the system disclosed by the Folgero et al. patent is pressurized.




U.S Pat. No. 4,967,827 to Campbell discloses a melting and casting apparatus in which electric radiant heating elements are used to heat molten metal passing from a holding furnace to a casting vessel. U.S. Pat. No. 5,398,750 to Crepeau et al. discloses a molten metal supply vessel in which a plurality of electric immersion heaters is used to heat molten metal in a holding furnace. The immersion heaters extend downward from the holding furnace cover and are partially submerged in the molten metal contained in the holding furnace. U.S. Pat. No. 5,567,378 to Mochizuki et al. discloses a similar immersion heater arrangement to that found in the Crepeau et al. patent.




The above-discussed radiant heating and immersion heating elements for heating molten metal in a holding furnace are located above the surface of the molten metal and are “top” heating arrangements. The “top” heating arrangements known in the art require a significant amount of space above the holding furnace for the individual heating elements. For example, the immersion heaters and electric radiant heaters discussed previously in connection with the Crepeau et al. and Campbell patents require a significant amount of space above the surface of the molten metal in the holding furnace, as well as a support structure above the holding furnace for supporting the heating elements above the surface of the molten metal. External heating arrangements, such as the burner arrangement disclosed by the Nakano patent, heat the holding furnace along a bottom wall or sidewall of the holding furnace and typically require space along the sides or bottom of the holding furnace for the heating elements. With such top/external heating arrangements, it is difficult to maintain a constant molten metal temperature in the holder furnace. In addition, with such top/external heating arrangements it is difficult to maintain a “clean” supply of molten metal. These arrangements are also generally known to contribute to metal oxide formation in the molten metal.




An alternative to top/external heating arrangements is to provide bottom heating devices in holding furnaces. Such bottom heating devices are typically embedded within the bottom wall of the holding furnace. One known bottom heating arrangement in a molten metal holding furnace is disclosed by U.S. Pat. No. 5,411,240 to Rapp et al. The heating cycle of such bottom heating arrangements places significant stress on the bottom wall of the holding furnace. Such embedded arrangements are also generally unsuitable for use with containment difficult metals such as molten aluminum alloys. Any leakage of molten aluminum alloy into the bottom wall of the holding furnace will cause failure of the embedded heating elements.




In view of the foregoing, an object of the present invention is to provide a bottom heated holder furnace for containing molten metal that frees space above the holder furnace. Another object of the present invention is to provide a bottom heated holder furnace that is suitable for use in a molten metal casting system. It is another object of the present invention to provide a bottom heated holder furnace which is suitable for use with molten aluminum alloys, eliminates restriction within the holder furnace, and is less likely to cause metal quality issues.




SUMMARY OF THE INVENTION




The above objects are accomplished with a molten metal holder furnace and molten metal casting system in accordance with the present invention. The holder furnace preferably contains a supply of molten metal that may be supplied to a casting mold through a plurality of molten metal injectors. The holder furnace includes 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 lines the molten metal receiving chamber of the storage vessel. A thermally conductive heat exchanger block is located at the bottom of the molten metal receiving chamber for heating the supply of molten metal. The heat exchanger block has a top face, a bottom face, and side faces. The heat exchanger block includes a plurality of electrical heaters 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. A sealing layer at least partially covers the bottom face and side faces of the heat exchanger block such that the heat exchanger block is substantially separated from contact with the furnace insulating layer.




The heat exchanger block may include a plurality of individual heat exchanger blocks connected together along side faces by a tongue-in-groove connection. The storage vessel may further include 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. A layer of refractory material may be located within the molten metal receiving chamber and on top of the heat exchanger block. The layer of refractory material may define a plurality of vertically extending chambers. The sealing layer may further partially cover 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 whereby the heat exchanger block may be in direct contact with molten metal when a supply of molten metal is contained in the storage vessel and the vertically extending chambers. The plurality of vertically extending chambers may be connected in series from the molten metal inlet to the molten metal outlet of the storage vessel.




A cover may be positioned on top of the storage vessel and substantially enclose the molten metal receiving chamber. The cover may define a plurality of openings corresponding to the plurality of vertically extending chambers for receiving, respectively, the plurality of molten metal injectors into the plurality of vertically extending chambers. A lift device may be 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, respectively, into the plurality of vertically extending chambers defined within the molten metal receiving chamber.




The sealing layer may further line the molten metal receiving chamber. The at least one furnace insulating layer may include a plurality of furnace insulating layers positioned between the sealing layer and the sidewalls and bottom wall of the storage vessel. The sealing layer may be an alumina fiber mat. The heat exchanger block may be made of graphite or silicon carbide.




The electrical heaters may extend between opposite sidewalls of the storage vessel and through the heat exchanger block. The electrical heaters may each include a continuous heating element extending through at least one of the opposite sidewalls, the at least one furnace insulating layer, and extending at least partially through the heat exchanger block. The electrical heaters may 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. The heating element for the electrical heaters may extend at least partially through each of the respective tubes. Sealing gaskets may be positioned within the heat exchanger block. The sealing gaskets may 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. The tubes may be ceramic insulating tubes that are substantially surrounded by a layer of ceramic fiber rope for preventing molten metal from leaking into the ceramic insulating tubes and contacting the heating element of the electrical heaters.




Flange plates may be attached, respectively, to the ceramic insulating tubes at the opposite sidewalls of the storage vessel. The ceramic insulating tubes may be held in compression against the opposite sidewalls of the storage vessel via the flange plates, bolts, and a plurality of Belleville washers stacked to yield about 175 pounds of torque on each of the ceramic insulating tubes. A source of inert gas may be 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.











Further details and advantages of the present invention will become apparent from the following detailed description in conjunction with the drawings wherein like parts are designated with like reference numerals throughout.




BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a cross-sectional end view of a holder furnace made in accordance with the present invention;





FIG. 2

is a cross-sectional end view of the holder furnace of

FIG. 1

viewed from an opposite end of the holder furnace from the cross-sectional view shown in

FIG. 1

;





FIG. 3

is a cross-sectional top view of the holder furnace of

FIGS. 1 and 2

taken along lines III—III in

FIG. 2

;





FIG. 4

is a cross-sectional side view of the holder furnace of

FIG. 1

;





FIG. 5

is a partial cross-sectional end view of the holder furnace of

FIG. 1

showing further details of a heat exchanger block used in the holder furnace; and





FIG. 6

is a front view, cross-sectional side view, and end view, respectively, of a ceramic insulating tube used in the heat exchanger block of FIG.


5


.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS





FIGS. 1 and 2

show a molten metal casting system


10


incorporating a molten metal holder furnace


12


in accordance with the present invention. The holder furnace


12


is discussed hereinafter in connection with the molten metal casting system


10


, but the present invention envisions the use of the holder furnace


12


in applications other than as part of the casting system


10


shown in

FIGS. 1 and 2

. For example, the holder furnace


12


may be used to supply molten metal to a degassing furnace or a molten metal filtration system. The casting system


10


of the present invention includes a casting mold


14


positioned above the holder furnace


12


. The casting mold


14


defines a mold cavity


16


for casting a metal component, such as an automobile part. Preferably, the casting mold


14


is configured to cast ultra-large, thin-walled metal components that may be used in a ground transportation vehicle such as an automobile. An ultra-large, thin-walled metal component part for a ground transportation vehicle may have dimensions approaching 3.0 meters long, 1.7 meters wide, and 0.4 meters in depth, and the mold cavity


16


of the casting mold


14


is preferably configured accordingly. The casting system


10


may also be used to cast metal component parts in the aircraft industry.




The casting mold


14


is preferably suitable for use with molten metal alloys having a low melting point, such as molten aluminum alloys. The casting mold


14


includes a holder frame


18


for supporting the casting mold


14


. The casting mold


14


is generally defined by a lower die


20


and an upper die


22


, which together define the mold cavity


16


. The casting mold


14


through the holder frame


18


is supported by a support surface or structure (not shown), or by other means customary in the art. For example, the casting mold


14


may be supported by a specially designed lower platen that extends downward from the holder frame


18


. The lower platen (not shown) is a box-like structure which extends downward from the holder frame


18


and encloses the upper portion of the holder furnace


12


. The lower platen may extend downward about four to six feet. The lower platen further preferably defines apertures through which a molten metal and molten metal outlet may extend to place the holder furnace


12


in fluid communication with a melter furnace, as discussed herein. The casting mold


14


may be located about one to two feet above the holder furnace


12


and, more particularly, the lower die


20


may be located about one to two feet above the holder furnace


12


in a preferred embodiment of the present invention.




The molten metal casting system


10


preferably further includes a plurality of molten metal injectors


24


supported from a bottom side


26


of the casting mold


14


. The injectors


24


generally provide fluid communication between the mold cavity


16


and the interior of the holder furnace


12


. The injectors


24


generally project downward from the bottom side


26


of the casting mold


14


into the holder furnace


12


. The injectors


24


may be supported with conventional mechanical fasteners attached to the holder frame


18


. Thus, the injectors


24


in a preferred embodiment of the present invention operate against the force of gravity. The injectors


24


are preferably further configured to provide low pressure, hot chamber injection of molten metal contained in the holder furnace


12


into the mold cavity


16


. Low pressure, hot chamber injection is particularly well suited for producing components made from non-ferrous metals having a low melting point, such as aluminum, brass, bronze, magnesium, and zinc. The molten metal casting system


10


illustrated in

FIGS. 1 and 2

is thus applicable for use in casting ultra-large, thin-walled component parts made of aluminum alloys. However, the casting system


10


and holder furnace


12


of the present invention may also be used to form metal component parts made from metals other than aluminum alloys.




The holder furnace


12


of the present invention will now be discussed in greater detail with reference to

FIGS. 1-4

. The holder furnace


12


is generally defined by a storage vessel


30


having sidewalls


32


and a bottom wall


34


, which enclose a molten metal receiving chamber


36


of the holder furnace


12


. The molten metal receiving chamber


36


is configured to contain a supply of molten metal


37


. For example, the molten metal receiving chamber


36


may be sized to contain about 2,000 pounds of molten metal


37


. The storage vessel


30


may be made of metal and, preferably, steel. The storage vessel


30


includes a base support structure


38


for supporting the holder furnace


12


. The support structure


38


includes wheels


40


, which make the holder furnace


12


transportable. Accordingly, the holder furnace


12


may be easily replaced in the molten metal casting system


10


shown in

FIGS. 1 and 2

. In the molten metal casting system


10


, a lift device


41


may be located beneath the support structure


38


of the holder furnace


12


for lifting the holder furnace


12


into engagement with the injectors


24


extending downward from the bottom side


26


of the casting mold


14


, as discussed further hereinafter. The lift device


41


may be a jack screw device or a hydraulic lift mechanism.




The holder furnace


12


includes a plurality of furnace lining layers


42


lining the molten metal receiving chamber


36


. In a preferred embodiment of the holder furnace


12


, three furnace lining layers


42


line the molten metal receiving chamber


36


. A first layer


44


of the furnace lining layers


42


lies immediately adjacent and in contact with the sidewalls


32


and bottom wall


34


of the storage vessel


30


. The first layer


44


is preferably a thermal insulation layer and may have a thickness of about one to three inches. The first layer


44


is preferably a microporous, primarily pressed silica powder (50-90%) material that is encapsulated in a woven fiberglass cloth. A suitable thermal insulating material for the first layer


44


includes Microtherm manufactured by Microtherm Inc., Maryville, Tenn.




A second layer


46


is positioned radially inward from the first layer


44


and is in contact therewith. The second layer


46


is preferably an aluminum-resistant, insulating, and castable material. The second layer


46


may be comprised of primarily silica and alumina, and is preferably light in weight and possesses low thermal conductivity properties. A suitable aluminum-resistant, lightweight, insulating, and castable material for the second layer


46


may include approximately 35% silica and 45% alumina by weight. A suitable aluminum-resistant, lightweight, insulating, and castable material for the second layer


46


includes ALSTOP™ Lightweight Castable manufactured by A. P. Green, Minerva, Ohio.




A third layer


48


of the furnace lining layers


42


lies radially inward from the second layer


46


and is in contact therewith. The third layer


48


is preferably a high alumina content castable layer. For example, the third layer


48


may include about 70-90% alumina by weight. A suitable material for the third layer


48


includes Grefcon™


80


A manufactured by RHI Refractories America and having an alumina content of about 80% by weight. The furnace lining layers


42


generally separate the sidewalls


32


and bottom wall


34


of the storage vessel


30


from the molten metal


37


contained in the molten metal receiving chamber


36


.




The surface of the molten metal receiving chamber


36


is preferably formed by a sealing layer


50


. The sealing layer


50


is preferably an alumina fiber mat material that lines the molten metal receiving chamber


36


. A suitable material for the sealing layer


50


is sold under the trademark SAFIL™ Alumina L D Mat, and manufactured by Thermal Ceramics, Augusta, Ga. The sealing layer


50


may, for example, include about 90-96% alumina fibers by weight.




The holder furnace


12


further includes a molten metal inlet


51


for receiving the molten metal


37


into the molten metal receiving chamber


36


defined by the storage vessel


30


, and a molten metal outlet


52


for removing the molten metal


37


from the holder furnace


12


. The holder furnace


12


is preferably in fluid communication through the molten metal inlet


51


and the molten metal outlet


52


with a main melter furnace (not shown), which typically contains a large quantity of molten metal that is used to continuously supply the holder furnace


12


with the molten metal


37


. The main melter furnace may contain on the order of 30,000 pounds of molten metal.




In operation, molten metal


37


flows from the main melter furnace through the molten metal inlet


51


and into the molten metal receiving chamber


36


. The molten metal outlet


52


is used to return the molten metal


37


to the main melter furnace. The molten metal


37


continuously circulates between the main melter furnace and the holder furnace


12


. Thus, “clean” molten metal


37


is always present in the holder furnace


12


because of the continuous circulation of the molten metal


37


between the main melter furnace and the holder furnace


12


. The molten metal inlet


51


and molten metal outlet


52


of the holder furnace


12


are preferably lined with a refractory material that is suitable for use with molten aluminum alloys. Suitable refractory materials include Permatech™ Sigma or Beta II castable refractory materials manufactured by Permatech Inc., Graham, N.C. Permatech™ Sigma refractory material is comprised of about 64% silica, 30% calcium aluminate cement, and 6% chemical frits by weight, and Permatech™ Beta II refractory material is comprised primarily of about 62% alumina and 29% silica by weight.




As shown in

FIGS. 1 and 2

, the holder furnace


12


includes a plurality of heat exchanger blocks


54


located at the bottom of the molten metal receiving chamber


36


. The heat exchanger blocks


54


are used to heat the molten metal


37


received in the molten metal receiving chamber


36


, as discussed further hereinafter. A plurality of vertically extending injector receiving chambers


56


is optionally formed within the molten metal receiving chamber


36


, and on top of the heat exchanger blocks


54


, as shown in

FIGS. 2-4

. The injector receiving chambers


56


are omitted from FIG.


1


.




The injector receiving chambers


56


are formed by a layer of refractory material


58


located on top of the heat exchanger blocks


54


. The layer of refractory material


58


is preferably suitable for use with molten aluminum alloy, such as Permatech™ Sigma or Beta II castable refractory materials discussed previously, or a substantially equivalent material. The injector receiving chambers


56


are preferably sized to accommodate the injectors


24


supported from the bottom side


26


of the casting mold


14


. In particular, when the holder furnace


12


is lifted into engagement with the injectors


24


by the lift device


41


, the injectors


24


are received, respectively, into the injector receiving chambers


56


. The injectors


24


are omitted in

FIG. 3

for clarity. As shown in

FIG. 3

, the injector receiving chambers


56


may be connected in series from the molten metal inlet


51


to the molten metal outlet


52


of the storage vessel


30


. Thus, molten metal from the main melter furnace may flow through the molten metal inlet


51


, sequentially into each of the injector receiving chambers


56


, and then return to the main melter furnace through the molten metal outlet


52


. The lift device


41


, as stated previously, is used to lift the holder furnace


12


into and out of engagement with the injectors


24


such that the injectors


24


are received, respectively, into the injector receiving chambers


56


.




A furnace cover


60


is positioned on top of the storage vessel


30


to substantially enclose the molten metal receiving chamber


36


. The furnace cover


60


preferably includes a plurality of openings


62


corresponding to the plurality of vertically extending injector receiving chambers


56


for receiving, respectively, the injectors


24


into the injector receiving chambers


56


. The furnace cover


60


may be made of metal, such as steel, and preferably includes an insulating layer


64


facing the molten metal receiving chamber


36


to protect the furnace cover


60


from contact with the molten metal


37


contained in the molten metal receiving chamber


36


. The insulating layer


64


is preferably an insulating blanket material. The insulating blanket material protects the furnace cover


60


from warping because of the high heat of the molten metal


37


in the molten metal receiving chamber


36


. Suitable materials for the insulating material include any of the materials discussed previously in connection with the furnace lining layers


42


, such as Microtherm, ALSTOP™ Lightweight Castable, and Grefcon™


80


A, or another substantially equivalent material. Another suitable material for the insulating layer


64


includes Maftec™ manufactured by Thermal Ceramics Inc., Augusta, Ga. This material is a heat storage multi-fiber blanket material that is heat resistant to about 2900° F.




As stated previously, the holder furnace


12


includes one or more heat exchanger blocks


54


located at the bottom of the molten metal receiving chamber


36


. The heat exchanger blocks


54


are used to heat the molten metal


37


contained in the molten metal receiving chamber


36


. Thus, the holder furnace


12


is generally heated from the bottom. The heat exchanger blocks


54


are thermally conductive and are preferably made of graphite, silicon carbide or another material having similar thermally conductive properties. The heat exchanger blocks


54


may be connected together along longitudinal side or end edges by a tongue-in-groove connection as shown, for example, in

FIGS. 1 and 2

. A preferred tapered angle of the tongue-in-groove connection is about 5°. The heat exchanger blocks


54


may be provided as a single, large heat exchanger block having dimensions conforming to the size of the molten metal receiving chamber


36


, or multiple blocks as stated hereinabove. The discussion hereinafter refers to a single heat exchanger block


54


for clarity.




In addition to forming the surface of the molten metal receiving chamber


36


, the sealing layer


50


, discussed previously, preferably also partially covers or encloses the heat exchanger block


54


. In particular, the sealing layer


50


preferably covers the heat exchanger block


54


on a bottom face


65


and side faces


66


of the heat exchanger block


54


, and may cover a portion of a top face


67


of the heat exchanger block


54


when the injector receiving chambers


56


are present. The remaining exposed portions of the top face


67


of the heat exchanger block


54


define heat transfer surfaces


68


of the heat exchanger block


54


, as shown in

FIGS. 2 and 4

. The heat transfer surfaces


68


are exposed areas along the top face


67


of the heat exchanger block


54


intended for direct contact with the molten metal


37


contained within the injector receiving chamber


56


. The heat transfer surfaces


68


transfer heat from the heat exchanger block


54


to the molten metal


37


contained in the respective injector receiving chamber


56


. Thus, the heat transfer surfaces


68


preferably substantially coincide with the injector receiving chambers


56


, and the flow passages connecting these chambers (shown in FIG.


3


), so that the heat exchanger block


54


may be in direct heat transfer contact with the molten metal


37


received in these chambers.




The sealing layer


50


may be omitted entirely from the top face


67


of the heat transfer block


54


if the injector receiving chambers


56


are not formed in the molten metal receiving chamber


36


, as shown in FIG.


1


. In this situation, the entire top face


67


of the heat exchanger block


54


is exposed and used to transfer heat to the molten metal


37


received within the molten metal receiving chamber


36


. In summary, the sealing layer


50


generally separates the bottom face


65


and side faces


66


of the heat exchanger block


54


from contact with the furnace lining layers


42


. Further, the sealing layer


50


may be used to separate portions of the top face


67


of the heat exchanger block


54


from contact with the layer of refractory material


58


forming the injector receiving chambers


56


when these chambers are present in the molten metal receiving chamber


36


.




The heat exchanger block


54


further includes a plurality of electrical heaters


70


which are used to heat the heat exchanger block


54


and, further, the molten metal


37


received in the molten metal receiving chamber


36


. The embodiment of the holder furnace


12


shown in

FIGS. 1 and 2

includes a total of twenty-four electrical heaters


70


. Thus, the three heat exchanger blocks


54


shown in

FIGS. 1 and 2

each include eight electrical heaters


70


. However, it will be appreciated by those skilled in the art that the respective heat exchanger blocks


54


may include any number of electrical heaters


70


. The electrical heaters


70


may, for example, be resistive type electrical heating heaters that extend completely or partially through the respective heat exchanger blocks


54


. For aluminum alloy applications, the electrical heaters


70


are preferably sized to maintain a system molten metal temperature of between about 1300-1500° F., and preferably about 1400° F.




The details of the heat exchanger block


54


and plurality of electrical heaters


70


shown in

FIGS. 1 and 2

will now be discussed in detail with reference to

FIGS. 4-6

. It will be apparent that the electrical heaters


70


in each of the three heat exchanger blocks


54


shown in

FIGS. 1 and 2

are identical, and a discussion of the details of one of the electrical heaters


70


will be illustrative of all of the electrical heaters


70


shown in

FIGS. 1 and 2

.




The electrical heater


70


, in a preferred embodiment, extends between opposite sidewalls of the storage vessel


30


. The opposite sidewalls of the storage vessel


30


are designated with reference numerals


32


A,


32


B, respectively, and will be referred to hereinafter as first sidewall


32


A and second sidewall


32


B for clarity. The electrical heater


70


preferably extends through the first sidewall


32


A, the furnace insulating layers


42


, the heat exchanger block


54


, and the second sidewall


32


B of the storage vessel


30


. In

FIGS. 4 and 5

, the electrical heater


70


extends substantially parallel to a longitudinal axis of the holder furnace


12


. However, the present invention envisions that the electrical heater


70


may be oriented transverse to the longitudinal axis of the holder furnace


12


, or at any other orientation as long as the electrical heater


70


extends substantially through the heat exchanger block


54


.




The electrical heater


70


includes a continuous heating element


76


that extends through the first sidewall


32


A, the furnace insulating layers


42


, and extends substantially through the heat exchanger block


54


. A portion


78


of the continuous heating element


76


projects outward from one of the side faces


66


of the heat exchanger block


54


. The opposite side faces of the heat exchanger block


54


are designated with reference numerals


66


A,


66


B, respectively, and will be referred to hereinafter as first side face


66


A and second side face


66


B for clarity. The continuous heating element


76


is preferably a resistive type electrical heating element.




The heating element


76


includes an end


80


, or “cold toe”, which terminates within the heat exchanger block


54


. The portion


78


of the heating element


76


that projects outward from the first side face


66


A of the heat exchanger block


54


is preferably enclosed by a first insulating tube


82


. The first insulating tube


82


extends through the first sidewall


32


A, the furnace lining layers


42


, and extends partially into the first side face


66


A of the heat exchanger block


54


. A second insulating tube


84


preferably extends through the second sidewall


32


B, the furnace insulating layers


42


, and extends partially into the second side face


66


B of the heat exchanger block


54


. A first sealing gasket


92


is located within the heat exchanger block


54


adjacent the end of the first insulating tube


82


extending into the heat exchanger block


54


at the first side face


66


A. The first sealing gasket


92


cooperates with the end of the first insulating tube


82


for preventing molten metal


37


from contacting the continuous heating element


76


. A second sealing gasket


94


is located within the heat exchanger block


54


adjacent the end of the second insulating tube


84


extending into the heat exchanger block


54


at the second side face


66


B. The second sealing gasket


94


cooperates with the end of the second insulating tube


84


extending into the heat exchanger block


54


at the second side face


66


B for preventing molten metal


37


from contacting the continuous heating element


76


.




The first and second insulating tubes


82


,


84


are preferably ceramic insulating tubes. The first and second sealing gaskets


92


,


94


are preferably made of an alumina fiber mat material having a high alumina fiber content similar to the material used for the sealing layer


50


. A suitable material for the first and second sealing gaskets


92


,


94


is sold under the trademark SAFIL™ Alumina L D Mat and manufactured by Thermal Ceramics, Augusta, Ga., as discussed previously in connection with the sealing layer


50


.




The first and second insulating tubes


82


,


84


are preferably each surrounded by a layer of ceramic fiber rope


100


for preventing molten metal


37


from leaking into the first and second insulating tubes


82


,


84


and contacting the continuous heating element


76


. A suitable ceramic fiber rope material includes Fiberfrax high density rope manufactured by the Carborundum Company, Niagara Falls, N.Y. Fiberfrax is comprised primarily of alumina-silica. Flange plates


102


are attached, respectively, to the first and second insulating tubes


82


,


84


at the first and second sidewalls


32


A,


32


B of the storage vessel


30


. The first and second insulating tubes


82


,


84


are preferably held in compression against the first and second sidewalls


32


A,


32


B of the storage vessel


30


by the flange plates


102


, bolts


104


, and a plurality of washers


106


. The washers


106


are preferably Belleville spring washers, which are stacked on the bolts


104


to yield about 175 pounds of torque on the first and second insulating tubes


82


,


84


. The first and second insulating tubes


82


,


84


are held in compression against the first and second sidewalls, or opposite sidewalls,


32


A,


32


B of the storage vessel


30


to counteract the thermal expansion of the heat exchanger block


54


under heating conditions.




The holder furnace


12


of the present invention may further include a source of inert gas


110


in fluid communication with the heat exchanger block


54


through the first and second insulating tubes


82


,


84


. The source of inert gas


110


provides inert gas, such as argon or nitrogen, to the interior of the heat exchanger block


54


such that the continuous heating element


76


of the electrical heater


70


operates in a substantially inert gas atmosphere. This prevents the heat exchanger block


54


, which is may be made primarily of carbon, from burning during operation of the holder furnace


12


. The electrical heater


70


and, more particularly, the continuous heating element


76


are connected to a source of electrical power


112


, which provides electrical power to the continuous heating element


76


. As stated previously, the construction of the electrical heater


70


discussed hereinabove is identical for each of the electrical heaters


70


used in the heat exchanger block


54


. A preferred embodiment of the holder furnace


12


includes three heat exchanger blocks


54


, each having a set of eight electrical heaters


70


.




In operation, when electrical power is supplied to the electrical heater


70


and, in particular, the continuous heating element


76


, the heat exchanger block


54


is heated. The exposed heat transfer surfaces


68


along the top face


67


of the heat exchanger block


54


, which are in contact with the molten metal


37


in the respective injector receiving chambers


56


, heat the molten metal


37


received in the injector receiving chambers


56


. The lift device


41


may be used to place the holder furnace


12


into and out of engagement with the injectors


24


supported from the bottom side


26


of the casting mold


14


. The lift device


41


may be a hydraulic lift table or a screw jack lifting device. The injectors


24


are configured to take in the molten metal


37


received in the injector receiving chambers


56


and inject the molten metal


37


under low pressure into the mold cavity


16


of the casting mold


14


.





FIG. 3

shows seven injector receiving chambers


56


for casting, for example, a liftgate of a minivan. The arrangement of the injector receiving chambers


56


in

FIG. 3

is specific to the liftgate of a minivan. As will be appreciated by those skilled in the art, the injector receiving chambers


56


may be formed in any manner in the molten metal receiving chamber


36


of the holder furnace


12


to form metal parts other than the liftgate of a minivan, or omitted altogether. The liftgate of a minivan is cited simply as an example. The holder furnace


12


is preferably positioned beneath the casting mold


14


and the injectors


24


received within the injector receiving chambers


56


prior to circulating molten metal from the melter furnace to the holder furnace


12


. As stated previously, the lift device


41


may be used to lift the holder furnace


12


into engagement with the injectors


24


. A programmable logic controller (not shown) preferably individually controls the injectors


24


such that the injectors


24


may be sequenced at different times and at different rates to fill the mold cavity


16


of the casting mold


14


completely with molten aluminum alloy, and to prevent the formation of air pockets within the mold cavity


14


and, ultimately, the cast part. For example, it may be advantageous to sequence the injection of molten aluminum alloy into the mold cavity


14


so that areas of the mold cavity


14


having greater volume are filled at a faster rate than those areas of the mold cavity


14


that are of smaller volume. The injectors


24


may be sequenced accordingly. The injectors


24


, as evidenced by the arrangement shown in

FIGS. 1

,


2


, and


4


, generally operate against the force of gravity, and are preferably selected for use with containment difficult metals such as aluminum alloys.




The present invention provides a bottom heated holder furnace for containing molten metal that frees space above the holder furnace for a casting mold. The holder furnace of the present invention is suitable for use with the previously described casting mold or another apparatus such as an aluminum degassing furnace or a molten metal filtration system. The present invention further provides a bottom heated holder furnace that is particularly well suited for use with molten aluminum alloys because the electrical heaters used to heat the holder furnace are isolated from contact with the molten aluminum. Furthermore, the holder furnace of the present invention may be used as part of a molten metal casting system for producing ultra-large, thin-walled component parts such as those that may be used in the automobile and aircraft industries.




While preferred embodiments of the present invention were described herein, various modifications and alterations of the present invention may be made without departing from the spirit and scope of the present invention. The scope of the present invention is defined in the appended claims and equivalents thereto.



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.

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