EP0444319A2 - Pression différentielle en coulée par contre gravité avec une introduction sélective d'alliages - Google Patents

Pression différentielle en coulée par contre gravité avec une introduction sélective d'alliages Download PDF

Info

Publication number: EP0444319A2
Authority: EP; European Patent Office
Prior art keywords: ingate; molten metal; alloyant; mold; mold cavity
Prior art date: 1990-02-27
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.): Withdrawn

Application number

EP19900125795

Other languages

German (de)

English (en)

Inventor

Richard J. Sabraw

Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)

Motors Liquidation Co

Original Assignee

General Motors Corp

Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)

1990-02-27

Filing date

1990-12-28

Publication date

1991-09-04

1990-12-28 Application filed by General Motors Corp filed Critical General Motors Corp

1991-09-04 Publication of EP0444319A2 publication Critical patent/EP0444319A2/fr

Status Withdrawn legal-status Critical Current

Links

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239000000155 melt Substances 0.000 abstract description 88
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239000010949 copper Substances 0.000 description 27
RYGMFSIKBFXOCR-UHFFFAOYSA-N Copper Chemical compound [Cu] RYGMFSIKBFXOCR-UHFFFAOYSA-N 0.000 description 25
229910052802 copper Inorganic materials 0.000 description 25
XEEYBQQBJWHFJM-UHFFFAOYSA-N Iron Chemical compound [Fe] XEEYBQQBJWHFJM-UHFFFAOYSA-N 0.000 description 19
239000002054 inoculum Substances 0.000 description 15
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WPBNNNQJVZRUHP-UHFFFAOYSA-L manganese(2+);methyl n-[[2-(methoxycarbonylcarbamothioylamino)phenyl]carbamothioyl]carbamate;n-[2-(sulfidocarbothioylamino)ethyl]carbamodithioate Chemical compound [Mn+2].[S-]C(=S)NCCNC([S-])=S.COC(=O)NC(=S)NC1=CC=CC=C1NC(=S)NC(=O)OC WPBNNNQJVZRUHP-UHFFFAOYSA-L 0.000 description 1
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Images

Classifications

- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22D—CASTING OF METALS; CASTING OF OTHER SUBSTANCES BY THE SAME PROCESSES OR DEVICES
- B22D27/00—Treating the metal in the mould while it is molten or ductile ; Pressure or vacuum casting
- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22D—CASTING OF METALS; CASTING OF OTHER SUBSTANCES BY THE SAME PROCESSES OR DEVICES
- B22D18/00—Pressure casting; Vacuum casting
- B22D18/06—Vacuum casting, i.e. making use of vacuum to fill the mould

Definitions

This invention relates to an improved apparatus and method for the differential pressure, countergravity casting of a melt in such a manner as to selectively introduce one or more alloyants into the melt as it is cast into the mold to tailor the metallurgical characteristics of the resultant casting, or local regions thereof.
a vacuum countergravity casting process using a gas permeable mold sealingly received in a vacuum housing is described in such patents as the Chandley et al U.S. Patents 3,900,064; 4,340,108 and 4,606,396. That countergravity process involves providing a mold having a porous, gas permeable upper mold member (cope) and a lower mold member (drag) sealingly engaged at a parting plane, sealing the mouth of a vacuum housing to a surface of the mold such that a vacuum chamber formed in the housing confronts the gas permeable upper mold member, submerging the under side of the lower mold member in an underlying melt and evacuating the vacuum chamber to draw the melt through one or more narrow ingates (pin gates) in the lower mold member and into one or more mold cavities formed between the upper and lower mold members.
the melt is typically prepared in a melting vessel (e.g., a cupola) using a charge of pig iron to which additions of alloyants are made to provide the desired base melt chemistry.
a melting vessel e.g., a cupola
pig iron to which additions of alloyants are made to provide the desired base melt chemistry.
ferromanganese Fe-Mn
Fe-Si ferrosilicon
other additions are made to the base pig iron charge to provide a desired base melt chemistry.
the melt is transferred from the melting vessel to a ladle where a nodularizing treating agent (e.g., Fe-Si-Mg) is added to spherodize the carbon.
a nodularizing treating agent e.g., Fe-Si-Mg
the treated base melt is then transferred from the ladle to a casting vessel to provide a melt pool from which a plurality of molds are successively vacuum countergravity cast.
the nodular iron castings produced in this manner exhibit an as-cast ferritic/pearlitic microstructure depending upon the melt composition and solidification rate.
the composition of the castings corresponds to that of the melt in the casting vessel.
the vacuum countergravity casting process as currently practiced has not had the capability of purposefully and controllably producing castings having different metallurgical characteristics at different locations in the casting so as to alter or enhance certain properties (e.g., mechanical properties) at localized regions of the casting as may be desired in certain service applications.
an alloyant is positioned at one or more ingates (e.g., pin gates) of the mold drag so as to be introduced into the melt as the melt is drawn upwardly through the ingates into the mold cavity to produce a casting having a composition different from that of the underlying melt.
reducing alloy additions and treating agent additions e.g., nodularizing agent additions
the present invention contemplates an improved apparatus and method for the differential pressure, countergravity casting of a melt wherein an alloyant is disposed on the mold at (i.e., within or in close proximity to) one or more of the ingates (e.g., narrow pin gates) to the mold cavity so as to contact the molten metal stream drawn upwardly through the ingate(s) into the mold cavity and selectively introduce the alloyant therein.
the composition of the melt is thereby altered as it is countergravity cast into the mold.
an expendable source of the alloyant is disposed at each of a plurality of the ingates such that the alloyant is introduced (e.g., dissolved) into the molten metal stream drawn upwardly through the ingate into the mold cavity to produce a casting having a different composition from that of the melt.
the alloyant introduced to the melt can be selected to provide a casting having different overall mechanical properties/microstructure from that obtainable from the melt.
copper can be introduced to a ferritic cast iron melt as it is drawn from the casting vessel upwardly into the mold cavity to produce a casting having a microstructure and substantially improved tensile and yield strength corresponding to a pearlitic cast iron grade.
a fugitive nodularizing agent e.g., Fe-Si-Mg
a fugitive nodularizing agent is disposed at each of a plurality of ingates so as to treat the melt as it is drawn upwardly from the casting vessel into the mold cavity for carbon nodularizing purposes.
the alloyant is disposed at some of the ingates to the mold cavity but not others so as to produce a casting having different compositions and resultant different metallurgical characteristics (e.g., different mechanical properties/microstructures) at different locations of the casting.
copper can be selectively introduced to the melt stream drawn upwardly into local regions of the mold cavity that form casting features requiring increased strength while other regions of the mold cavity that form casting features not requiring such strength receive untreated melt (i.e., melt devoid of copper).
a first alloyant source can be disposed at some ingates while a second alloyant source is disposed at other ingates to produce a casting having different metallurgical characteristics at different locations.
molds configured to produce a particular cast part include a source of alloyant at one or more mold ingates while other molds configured to produce a different cast part are without such alloyant sources or perhaps include a source of a different alloyant at one or more ingates.
the molds are successively countergravity cast from the same underlying melt to produce the different cast parts having different compositions tailored for different end uses from the common underlying melt.
molds configured to produce a particular part can be countergravity cast from an underlying ferritic nodular iron grade melt with no alloyant disposed on the molds while other molds configured to produce a different part (e.g., a connecting rod) can be countergravity cast from the same melt with a suitable alloyant disposed at the ingates to alter the composition of the ferritic nodular iron melt drawn into the mold cavity to produce a microstructure and improved mechanical properties corresponding to a pearlitic cast iron grade as desired for connecting rods.
a suitable alloyant disposed at the ingates to alter the composition of the ferritic nodular iron melt drawn into the mold cavity to produce a microstructure and improved mechanical properties corresponding to a pearlitic cast iron grade as desired for connecting rods.
the present invention also contemplates a mold cavity fill analysis method for determining molten metal flow paths from the ingates into the mold cavity during differential pressure, countergravity casting from an underlying melt.
a source of alloyant that affects a metallurgical characteristic of the casting is disposed at a particular ingate such that the alloyant is selectively introduced into the melt drawn upwardly through the particular ingate and is not introduced into the melt drawn upwardly through other adjacent ingates.
the resulting casting is examined (e.g., metallographically) to observe the distribution of the metallurgical characteristic in the casting attributable to introduction of the alloyant to the melt at the particular ingate.
the molten metal flow path from the particular ingate into the mold cavity can be determined.
This procedure can be repeated for each ingate to determine melt flow paths from the ingates into the mold cavity.
the results of such analysis can be used to improve mold ingating designs and eliminate casting defects resulting from inadequate ingating, thus providing higher quality castings.
Figure 1 is a sectioned, side view of a vacuum countergravity casting apparatus in accordance with the invention.
Figure 2 is an enlarged sectional view of the ingate encircled in Fig. 1.
Figure 3 is a bottom elevation of the ingate shown in Fig. 2.
Figure 4 is a bottom elevation of the mold drag taken in the direction of arrows 4-4 of Fig. 1.
Figure 5 is a bottom elevation of the mold drag of another embodiment of the invention.
Figure 6 is a bottom elevation of a particular ingate wherein alloyant needles are disposed in the ingate.
Figure 7 is a bottom elevation of a particular ingate wherein alloyant plates or vanes are disposed in the ingate.
Figure 8 is a bottom elevation of a particular ingate wherein a tubular alloyant pellet is embedded in the underside of the mold drag coaxially about the ingate.
Figure 9 is a bottom elevation of a particular ingate wherein a solid alloyant disc is disposed in the ingate.
Figure 10 is a sectional view of a particular ingate wherein the alloyant source is disposed adjacent the outlet of the ingate.
Figure 11 is a sectional view of a particular ingate wherein the alloyant source is disposed in a pocket formed in the ingate of a two-part mold drag.
Figures 12, 13 and 14 are top elevational views of similar cast exhaust manifolds shaded to illustrate the presence of primary carbides bounding localized carbide-free regions resulting from positioning a Fe-Si inoculant pellet at ingate 1 in Fig. 12, at ingate 4 in Fig. 13 and at ingate 6 in Fig. 14.
Figure 15 is a longitudinal sectional view along lines 15-15 of Fig. 14.
Figure 1 depicts a pool 2 of melt 4 which is to be drawn up into a mold 6 having a gas-permeable upper mold portion 8 (cope) and a lower mold portion 10 (drag) joined at a parting line 12 and defining a molding cavity 14 therebetween.
the melt 4 is contained in a casting furnace or vessel 3 heated by one or more induction coils (not shown) to maintain the melt 4 at a desired casting temperature.
the lower mold portion 10 includes a plurality of narrow ingates 16 (i.e., pin gates) communicating the underside 10a thereof with the mold cavity 14 for admitting the melt 4 to the mold cavity 14 when it is evacuated through the upper mold portion 8 with the underside 10a immersed in the melt 4.
the ingates (pin gates) 16 preferably have a major dimension (e.g., diameter for cylindrical ingates) not exceeding about 0.50 inch, preferably not exceeding 0.25 inch (e.g., .1875 inch) for purposes set forth in U.S. Patent 4,340,108 and hereinafter described.
the lower mold portion 10 of the mold 6 is sealed to the mouth 18 of a vacuum box 20 defining a vacuum chamber 22 via a seal 24 (e.g., high temperature rubber, ceramic rope, etc.).
the seal 24 is affixed to the lower peripheral edge of the depending peripheral side 25 of the vacuum box 20.
the vacuum chamber 22 encompasses the upper mold portion 8 and communicates with a vacuum source 23 (e.g., a vacuum pump) via conduit 26.
the upper mold portion 8 comprises a gas-permeable material (e.g., resin-bonded sand) which permits gases to be withdrawn from the casting cavity 14 therethrough when a vacuum is drawn in the chamber 22.
the lower mold portion 10 may conveniently comprise the same material as the upper mold portion 8 or other materials, permeable or impermeable, which are compatible with the material of the upper mold portion 8.
the lower mold portion 10 includes an upstanding levee 26 surrounding the seal 24 and isolating it from the melt 4 as described in U.S. Patent 4,745,962 and assigned to the assignee of the present invention.
the lower mold portion 10 includes a plurality of anchoring sites 28 engaged by T-bar keepers 30 of the type described in commonly assigned U.S. patent application Serial No. 147,863, abandoned in favor of patent application Serial No. 286,051, providing means for mounting the mold 6 to the vacuum box 20.
the lower mold portion 10 includes a plurality of anchoring cavities 32 adapted to receive the T-bar keepers 30 via slots 34 in the shelves 40 overlying the anchoring cavities 32 and attached to the lower mold portion 10.
a 90° rotation of the T-bar carrying shafts 36 e.g., by air motors 38
Other known mold to vacuum box mounting means can also be employed in practicing the invention (e.g., U.S. Patent 4,658,880).
the upper mold portion 8 is pressed into sealing engagement with the lower mold portion 10 (i.e., at the parting line 12) by means of a plurality of plungers 42 so as to eliminate the need to glue the upper mold portion 8 and the lower mold portion 10 at the parting plane 12.
Feet 44 on the ends of the plungers 42 distribute the force of the plungers 42 more widely across the top of the upper mold portion 8 to prevent penetration/puncture thereof by the ends of the plungers 42.
Pneumatic springs 46 bias the plungers 42 downwardly to resiliently press the upper mold portion 8 against the lower mold portion 10 as the mold 6 is being positioned in the mouth 18 of the vacuum box 22.
Schrader valves 48 on the air springs 46 permit varying the pressure in the springs 46 as needed to apply sufficient force to press the upper mold portion 8 into sealing engagement with the lower mold portion 10, and, as needed, to prevent destructive inward flexure of the mold 6 when the casting vacuum is drawn.
the force applied by the plungers 42 will not be so great as to overpower and damage the anchoring sites 28, dislodge the mold 6 from the mouth 13 of the box 20, or break the seal formed thereat.
Countergravity casting of each casting mold 6 is effected by relatively moving each mold 6 and the pool 2 to immerse the underside 10a of the lower mold portion 10 in the melt 4 and evacuating the mold cavity 14 to draw the melt 4 upwardly through the ingates 16 into the mold cavity 14.
the casting mold 6 is lowered toward the pool 2 using a hydraulic power cylinder 60 (shown schematically) actuating a movable support arm 62 (shown schematically) that is connected to the vacuum box 20.
each casting mold 6 is raised by hydraulic power cylinder 60 to withdraw the underside 10a of the lower mold portion 10 out of the pool 2.
the number and size of the ingates 16 to achieve metal solidification initially at the ingates 16 can be selected in accordance with the teachings of U.S. Patent 4,340,108.
the molten iron can be allowed to solidify in both the ingates 16 and the mold cavity 14 before raising the casting mold.
a first embodiment of the invention is illustrated for altering the composition of a ferritic nodular iron grade melt 4 as it is drawn upwardly through the narrow ingates (pin gates) 16 into the mold cavity 14 during the vacuum countergravity casting process described hereinabove.
this embodiment involves altering the melt composition to produce a casting having not only a different composition (e.g., by inclusion of copper in the melt) but also a different microstructure (e.g., a pearlitic cast iron grade microstructure) from that obtainable by solidification of the ferritic nodular iron melt 4.
the melt 4 is prepared initially as a ferritic iron base melt in a melting vessel, such as for example a cupola (not shown), by the addition of suitable alloyants to a pig iron charge in the melting vessel.
suitable alloyants for example, additions of 49 lbs. of 50% Fe-Si, 50 lbs. of steel, 2.5 lbs. of Fe-Mn and 1 lb. of graphite are made to 1150 lbs.
total carbon 3.60 to 4.10 w/o
Mn .25 to .90 w/o
P .05 w/o max
S .02 w/o max
Si 2.20 to 2.70 w/o
Cr .10 w/o max
a portion (e.g., 300 lbs.) of the ferritic iron base melt is transferred to a ladle (not shown) where the melt is treated with a nodularizing treating agent (e.g., Fe-Si-Mg having a nominal composition of about 5 w/o Mg and balance Fe and Si in equal amounts) to spherodize the carbon.
a nodularizing treating agent e.g., Fe-Si-Mg having a nominal composition of about 5 w/o Mg and balance Fe and Si in equal amounts
a Mg content of about 0.03-0.06 w/o is typically provided in the ferritic iron base melt for this purpose. Cut steel shavings are introduced as a cover layer over the treated base melt in the ladle to enhance recovery of magnesium.
the resulting ferritic nodular iron grade melt 4 (i.e., 300 lbs.) is then transferred from the ladle to the casting vessel 3 where the melt 4 is inoculated by the addition of 2 lbs. of Fe-Si alloyant and the melt temperature is maintained at about 2600°F during the vacuum countergravity casting of successive molds 6 therefrom.
an expendable source 50 of copper alloyant is positioned at each ingate 16 so as to selectively introduce (e.g., dissolve) copper into the ferritic nodular iron grade melt 4 as a stream of the melt 4 is drawn upwardly through the ingates 16 into the molding cavity 14 during the vacuum, countergravity casting process.
the mold 6 includes the sources 50 of copper alloyant in each ingate (pin gate) 16 adjacent the inlet thereof (i.e., adjacent the underside 10a of the lower mold portion 10).
Each source 50 of copper alloy comprises a spiral of copper electrical wire wedged in each ingate 16 adjacent the underside 10a with the axis of the spiral coaxial with the longitudinal axis or each ingate 16, see Figs. 2-3. It is apparent that the configuration and orientation of the spiral wire source 50 provides a plurality of upwardly extending passages 52 through which the ferritic nodular iron melt stream can be drawn upwardly from the pool 2 into the mold cavity 14 during the vacuum countergravity casting process.
the melt 4 passes through the passages 52 in the spiral wire source 50 for intimate contact therewith and introduction (e.g., dissolution) of copper selectively into the melt 4 flowing through each respective ingate 16.
the amount of copper introduced into the melt 4 is selected (e.g., about .4 w/o minimum to about .5 w/o maximum) to provide a microstructure upon solidification of the melt 4 in the mold cavity 14 (during air cooling of the metal-filled mold 6) and improved tensile and yield strength properties at least comparable to the known as-cast pearlitic nodular iron grade 5203.
the castings tensile specimens
the castings were found to exhibit an as-cast microstructure corresponding to the known as-cast pearlitic nodular iron grade 5203 (e.g., 50 v/o ferrite max., 50 v/o pearlite min., 10 v/o carbide max.) and mechanical properties more than comparable (see Table I below) to the as-cast pearlitic nodular iron grade 5203.
the known as-cast pearlitic nodular iron grade 5203 e.g., 50 v/o ferrite max., 50 v/o pearlite min., 10 v/o carbide max.
mechanical properties more than comparable see Table I below
each source 50 of copper can be positioned in the conventionally shaped/sized narrow ingates (pin gates) 16 without having to make substantial modifications to the ingates 16.
the ingates 16 can be configured sufficiently narrow (e.g., .1875 inch in diameter for the cylindrical ingates 16 shown) to effect initial freeze-off of the melt 4 in the ingates 16 in accordance with U.S. Patent 4,340,108 and yet still achieve desired introduction of the alloyant (Cu) in the melt 4 during casting.
a somewhat different embodiment of the invention is illustrated and involves positioning the sources 50 of copper (or other) alloyant soluble in the melt 4 at some ingates 16 but not other ingates 16' to produce a casting having different metallurgical characteristics (e.g., different microstructures/mechanical properties) at different locations of the casting.
the sources 50 of copper alloyant are placed at some ingates 16 to feed a certain region R of the mold cavity 14 with the copper-modified melt 4 described hereinabove (i.e., a melt 4 containing copper in desired amount) to produce a pearlitic cast iron grade microstructure and improved mechanical properties upon solidification in the region R of the mold cavity 14.
region L of the mold cavity 14 receives the ferritic nodular iron melt 4 substantially devoid of copper from the ingates 16' (where there are no sources 50 of copper alloyant) so as to produce a microstructure (e.g., 40 v/o ferrite min., 60 v/o pearlite max., 10 v/o carbide max.) and reduced mechanical properties (e.g., nominal tensile strength of 60,000 psi, nominal yield strength of 40,000 psi and nominal elongation of 10%) corresponding to the known as-cast ferritic nodular iron grade 4010 upon solidification of the melt 4 in the region L of the mold cavity 14.
a microstructure e.g., 40 v/o ferrite min., 60 v/o pearlite max., 10 v/o carbide max.
reduced mechanical properties e.g., nominal tensile strength of 60,000 psi, nominal yield strength of 40,000 psi and nominal elongation of 10%
Region R of the mold cavity 14 would correspond to a location of the casting requiring increased strength while region L would correspond to a location of the casting not requiring the higher strength but perhaps requiring more ductility. Dual property, vacuum-assisted countergravity castings can thereby be produced.
an expendable source (not shown) of a second alloyant may be positioned at one or more of the ingates 16' while the copper alloyant sources 50 are positioned at the ingates 16 such that a first alloyant (i.e., copper) is introduced into the melt 4 drawn upwardly through one or more of the narrow ingates (pin gates) 16 while the second alloyant is introduced into the melt 4 drawn upwardly through one or more of the ingates 16'.
a first alloyant i.e., copper
pin gates narrow ingates
castings having different metallurgical characteristics at different locations can also be cast in accordance with the invention by introducing a first amount of an alloyant into the melt 4 drawn upwardly through one or more ingates 16 while a different amount of the same alloyant is introduced into the melt 4 drawn upwardly through one or more of the other ingates 16'.
the position (i.e., proximity) of the sources 50 relative to the ingates 16,16' as well as the size and configuration of the alloyant sources 50 can be varied to achieve introduction of different amounts of the same alloyant into the melt 4 drawn through different ingates 16,16' during the vacuum-assisted countergravity casting process.
different cast parts having different metallurgical characteristics for different intended uses can be vacuum countergravity cast from a common melt using the apparatus shown in Fig. 1.
a plurality of the molds 6 having one or more connecting rod-shaped mold cavities 14 and copper alloyant sources 50 at each of the ingates 16 can be vacuum countergravity cast in succession from the ferritic nodular iron melt 4 as described hereinabove to produce cast connecting rods having an as-cast microstructure and mechanical properties at least equivalent to as-cast pearlitic nodular iron grade 5203.
a plurality of other molds 6 having one or more exhaust manifold-shaped mold cavities 14 but without copper alloyant sources 50 at any of the ingates 16 can be vacuum countergravity cast in succession from the same (common) ferritic nodular iron melt 4 to produce exhaust manifolds having an as-cast microstructure and mechanical properties corresponding to as-cast ferritic nodular iron grade 4010.
the molds for casting the connecting rods and the molds for casting the exhaust manifolds can be cast in any sequence desired since both types of molds are cast from the common ferritic nodular iron melt 4.
This embodiment of the invention eliminates the need to prepare and handle different base melts in one or more melting vessels/ladles.
a "universal" cupola melt can be used to produce different cast parts having different compositions and/or microstructures and resultant mechanical properties.
the manufacture of different cast parts for different intended uses is thus simplified.
the flexibility of the vacuum countergravity casting process in meeting ever changing production schedule variations is tremendously improved.
Figs. 1-5 illustrate the sources 50 as spiral wound wire disposed in the ingates 16 adjacent the underside 10a of the lower mold portion 10, the invention is not so limited.
the sources 50 may assume other configurations as illustrated in Figs. 6, 7, 8 and 9.
the alloyant source 50' comprises a plurality of circumferentially spaced alloyant needles 51' extending toward the center of the ingate (pin gate) 16'.
Fig. 7 illustrates the alloyant source 50'' as comprising a plurality of spaced apart alloyant plates 53'' disposed in the ingate (pin gate) 16'' for contact with the melt drawn upwardly therethrough.
Fig. 1-5 illustrate the sources 50 as spiral wound wire disposed in the ingates 16 adjacent the underside 10a of the lower mold portion 10
the invention is not so limited.
the sources 50 may assume other configurations as illustrated in Figs. 6, 7, 8 and 9.
the alloyant source 50' comprises a plurality of circumferentially spaced alloyant needles 51'
the source 50''' is illustrated as a solid, cylindrical, tubular alloyant pellet 54'''' disposed about the ingate (pin gate) 16''' coaxial therewith for communicating directly with the ingate.
the alloyant source 50'''' comprises a solid disc 52'''' of the alloyant positioned across the ingate 16''''.
solid disc 52'''' in the ingate 16'''' the underside of the mold 6 is immersed in the melt 4 (see Fig.
the sources 50, 50', etc. can be held in the respective ingates (pin gates) 16, 16', etc. using sodium silicate or other suitable adhesive.
the sources 50, 50', etc. can be embedded in the lower mold portion 10 in such a position as to extend in the desired manner into the ingate 16, 16', etc. as shown in Figs. 6-9.
the alloyant source is embedded in the lower mold portion 10 while the sand-resin mixture thereof is compliant. Then, the sand-resin mixture of the lower mold portion 10 is cured or hardened to retain the alloyant sources in position.
Figs. 1-9 illustrate each alloyant source 50, 50', etc. as being disposed adjacent the inlet of the respective ingates 16, 16', etc.
the invention is not so limited.
the cylindrical, tubular alloyant source 150 in the form of the cylindrical, tubular alloyant pellet 154) can be disposed adjacent the outlet 116a of the respective ingate 115 in the lower mold portion 110 and in the mold cavity 114 formed between the upper and lower mold portions 108,110.
the alloyant source 250 can be disposed in a small pocket 217 formed in the narrow pin gate 216 at a parting plane P of a two-part lower mold portion (drag) 210.
the pocket 217 is located in the upper portion 210 of the two-part lower mold portion (drag) 210 intermediate the inlet 216a and outlet 216b of the narrow pin gate 216.
the pin gate 216 is of the type described hereinabove sized to effect initial, rapid solidification of a plug of metal therein after the mold cavity 214 is filled with molten metal.
the pin gate 216 supplies the treated molten metal stream drawn therethrough to the mold cavity 214 formed in the upper mold portion (cope) 208.
the outer periphery of the source alloyant 250 includes slots 250a to provide a molten metal flow path through the pin gate 216.
the alloyant source 50, 50', etc. need not communicate directly with the ingate 16, 16', etc. so long as the alloyant source is in sufficiently close proximity to the ingate to contact the melt 4 drawn upwardly through the ingate 16 and selectively introduce the alloyant into the melt 4 drawn upwardly therethrough.
the source 50, 50', etc. can be embedded in the underside 10a of the lower mold portion 10 in the manner described in the copending application (attorney docket no. P-309 GM-Plant) spaced from the inlet of the ingate 16,16', etc. and yet sufficiently close to the inlet of the ingate 16, 16', etc. as to introduce the alloyant into the stream of melt 4 drawn upwardly into that particular ingate 16, 16', etc.
an iron-silicon-magnesium nodularizing agent having a composition of about 5 w/o Mg and balance Fe and Si in equal amounts
This method of introducing the nodularizing agent into the melt 4 as it is drawn upwardly through the ingates 16 can be used in lieu of or in addition to the method disclosed in the aforementioned copending application (attorney docket no.
P-309 GM-Plant of common assignee herewith for maintaining the magnesium content of the melt 4 at the required level (e.g., about 0.03 w/o-0.06 w/o) for nodularizing the carbon of the melt 4 filling the mold cavity 14 of successively cast molds 6. Loss or "fade” of the magnesium content of the melt 4 over time can be thereby countered.
the sources 50 may comprise a Fe-Si inoculant (comprising 1 w/o Ca, 75 w/o Si and balance Fe) for promoting nucleation of graphite in the ferritic (or pearlitic) nodular iron grade melt 4 during solidification.
a source 50 of Fe-Si inoculant in the form of a tubular solid pellet as shown in Fig. 8) was positioned about each ingate 16 adjacent the underside 10a of the lower mold portion 10 prior to vacuum countergravity casting of a ferritic nodular iron melt 4.
the inoculant sources 50 were effective to introduce inoculant into the melt 4 drawn upwardly through the ingates 16 into the mold cavity 14 in such a quantity as to significantly increase the graphite nodule count in the casting; e.g., to 161.3 nodules per square millimeter.
the present invention is not limited to the vacuum countergravity casting of cast irons and instead may be used in the vacuum countergravity casting of other metals/alloys where selective introduction of one or more alloyants is desired for some purpose.
the present invention may be used to dissolve known degassing, desulfurizing, deslagging and similar treating agents into aluminum or steel during the vacuum countergravity casting thereof.
the invention also envisions a mold cavity fill analysis method for determining melt flow paths into the mold cavity 14 from the ingates 16 during the countergravity casting process.
an alloyant source 50 is disposed in close proximity to a selected one of the ingates 16 (instead of all the ingates 16 as shown) so as to introduce the alloyant only into the melt 4 drawn upwardly through that particular ingate.
the alloyant is selected to impart a particular metallurgical characteristic to the casting which metallurgical characteristic will be localized to a region of the mold cavity 14 that is supplied melt 4 by the particular ingate 16 where the source 50 is placed.
Regions of the casting receiving melt 4 from the other ingates 16 where there are no alloyant sources will not exhibit this metallurgical characteristic.
the contribution of a particular ingate 16 (where the alloyant source is placed) to the filling of the mold cavity 14 can be determined based on an analysis of the solidified casting; i.e., to determine where the particular metallurgical characteristic appears in the casting. This procedure can be repeated for each ingate 16 (or multiple ingates 16 when they are sufficiently remote from one another) to determine melt flow paths into the mold cavity 14 from each ingate.
Figs. 12-15 illustrate application of this method to the vacuum countergravity casting of automobile engine exhaust manifolds 100, 100', 100'' (schematically shown) using an apparatus similar to that shown in Fig. 1 with the exception that a single alloyant source 50 is disposed in proximity to one, but not others, of the ingates 16.
the locations of the ingates on the cast exhaust manifolds 100, 100', 100'' are numbered from #1 to #15 in Figs. 12-14 for identification purposes.
the exhaust manifold 100 was vacuum countergravity cast with a solid tubular Fe-Si inoculant pellet embedded in the underside 10a of the lower mold portion 10 about the inlet of ingate #1, e.g., as shown in Fig. 8.
a nodular iron melt 4 depleted of its graphite nucleating ability was then vacuum countergravity cast into the mold cavity 14 and solidified.
the nodular iron melt 4 drawn upwardly through ingate #1 contacted the Fe-Si inoculant pellet embedded in proximity to the ingate #1 such that the inoculant was introduced therein.
the quantity of inoculant introduced into the melt 16 at the ingate #1 was sufficient to promote formation of graphite nodules and inhibit formation of primary carbides during solidification of the melt 4 in those regions of mold cavity 14 receiving the melt 4 from ingate #1.
Those regions of the mold cavity 14 filled through the other ingates 16 received melt which was substantially devoid of inoculant and which, as a result, solidified as "white” cast iron with primary carbide precipitation and little or no graphite nodule formation.
a noticeable metallurgical characteristic was associated with selective introduction of the inoculant into the melt passing through the ingate #1.
the resultant exhaust manifold 100 was then sectioned at various locations for metallographic examination.
Fig. 12 includes shaded areas A where primary carbides of the varying percentages shown were found upon sectioning of the casting.
the shaded areas A indicate those regions of the casting (or mold cavity 14) that are not fed by the ingate #1. These shaded areas A bound or enclose those regions of the casting that are fed with the melt containing inoculant from ingate #1. From Fig. 12, it is apparent that the ingate #1 feeds only a portion of flange area F1 of the cast exhaust manifold 100.
Fig. 13 includes shaded areas A' where carbides of the varying percentages shown were observed in the cast exhaust manifold 100' when the Fe-Si inoculant pellet was disposed at only the ingate #4 to selectively introduce silicon into the melt drawn upwardly through that ingate #4. It is apparent that the ingate #4 feeds the melt primarily to the flange area F2 of the cast exhaust manifold 100'. Fig. 13 also reveals that the ingates #3, #8 and/or #9 also supply melt to this same flange area F2. The flow of melt to the flange area F2 from ingates #3, #8 and/or #9 was not planned or expected during the design of the gating system for the particular mold involved.
Fig. 14 includes shaded areas A'' where primary carbides of the varying percentages shown were observed in the cast exhaust manifold 100'' when the Fe-Si inoculant pellet was disposed at only ingate #6 to selectively introduce the inoculant into the melt drawn upwardly through the ingate #6.
FIG. 12 A comparison of Figs. 12 and 14 reveals that the ingate #6 feeds a much larger area of the cast exhaust manifold 100'' than the ingate #1. Moreover, melt flow through the ingate #6 is effective enough to blend with melt entering the flange area F1 through the ingate #1.
Fig. 15 is a longitudinal sectional view through the flange area F1 of the cast exhaust manifold 100'' and reveals massive carbides at the back side of the flange area F1. The presence of these massive carbides suggests that the ingate #1 feeds melt to the flange area F1 prior to ingate #6 and that solidification in that local region (where massive carbides are observed) began prior to arrival of the melt from the ingate #6.
the mold cavity fill analysis method of the invention illustrated hereinabove with reference to Figs. 12-15 provides to the casting engineer a tool for determining melt flow patterns from particular ingates 16 into the mold cavity 14 during vacuum-assisted countergravity casting of molten metal.
This method will help the casting engineer to improve and optimize mold gating systems for a particular casting to be produced.
This method also will help reduce the development and lead times required to design a particular casting mold and thus facilitate meeting scheduling demands for production castings.
the prospect of producing quality castings on a production basis should be improved as a result.

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EP19900125795 1990-02-27 1990-12-28 Pression différentielle en coulée par contre gravité avec une introduction sélective d'alliages Withdrawn EP0444319A2 (fr)

Applications Claiming Priority (2)

Application Number	Priority Date	Filing Date	Title
US48596990A	1990-02-27	1990-02-27
US485969		1990-02-27

Publications (1)

Publication Number	Publication Date
EP0444319A2 true EP0444319A2 (fr)	1991-09-04

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ID=23930109

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Application Number	Title	Priority Date	Filing Date
EP19900125795 Withdrawn EP0444319A2 (fr)	1990-02-27	1990-12-28	Pression différentielle en coulée par contre gravité avec une introduction sélective d'alliages

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Country	Link
EP (1)	EP0444319A2 (fr)
JP (1)	JPH04224070A (fr)
BR (1)	BR9100247A (fr)
CA (1)	CA2030496A1 (fr)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
EP0562170A1 (fr) *	1992-03-26	1993-09-29	General Motors Corporation	Pression différentielle en coulée par contre-gravité

Families Citing this family (1)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
DE112006000461T5 (de)	2005-02-22	2008-03-13	Milwaukee School Of Engineering, Milwaukee	Gießverfahren

1990
- 1990-11-21 CA CA 2030496 patent/CA2030496A1/fr not_active Abandoned
- 1990-12-28 EP EP19900125795 patent/EP0444319A2/fr not_active Withdrawn
1991
- 1991-01-21 BR BR9100247A patent/BR9100247A/pt unknown
- 1991-02-26 JP JP5313891A patent/JPH04224070A/ja not_active Withdrawn

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
EP0562170A1 (fr) *	1992-03-26	1993-09-29	General Motors Corporation	Pression différentielle en coulée par contre-gravité

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Publication number	Publication date
JPH04224070A (ja)	1992-08-13
CA2030496A1 (fr)	1991-08-28
BR9100247A (pt)	1991-10-22

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Date	Code	Title	Description
1991-07-18	PUAI	Public reference made under article 153(3) epc to a published international application that has entered the european phase	Free format text: ORIGINAL CODE: 0009012
1991-09-04	AK	Designated contracting states	Kind code of ref document: A2 Designated state(s): DE FR GB IT
1992-07-14	STAA	Information on the status of an ep patent application or granted ep patent	Free format text: STATUS: THE APPLICATION HAS BEEN WITHDRAWN
1992-07-29	18W	Application withdrawn	Withdrawal date: 19920610
1992-09-02	R18W	Application withdrawn (corrected)	Effective date: 19920610

Publication	Publication Date	Title
CA1239010A (fr)	1988-07-12	Coulee du metal
US3658115A (en)	1972-04-25	Method of inoculating nodular cast iron
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EP0067500A1 (fr)	1982-12-22	Procédé de moulage de fonte contenant du graphite compact par inoculation dans le moule
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EP0444319A2 - Pression différentielle en coulée par contre gravité avec une introduction sélective d'alliages - Google Patents

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