US3229337A - Furnace ladling apparatus - Google Patents

Furnace ladling apparatus Download PDF

Info

Publication number
US3229337A
US3229337A US225706A US22570662A US3229337A US 3229337 A US3229337 A US 3229337A US 225706 A US225706 A US 225706A US 22570662 A US22570662 A US 22570662A US 3229337 A US3229337 A US 3229337A
Authority
US
United States
Prior art keywords
chamber
storage tank
molten metal
pump
gas
Prior art date
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.)
Expired - Lifetime
Application number
US225706A
Inventor
Holz George William
Hugh E Pollard
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.)
Lindberg Engineering Co
Original Assignee
Lindberg Engineering Co
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.)
Filing date
Publication date
Application filed by Lindberg Engineering Co filed Critical Lindberg Engineering Co
Priority to US225706A priority Critical patent/US3229337A/en
Application granted granted Critical
Publication of US3229337A publication Critical patent/US3229337A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F27FURNACES; KILNS; OVENS; RETORTS
    • F27DDETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS, OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
    • F27D3/00Charging; Discharging; Manipulation of charge
    • F27D3/14Charging or discharging liquid or molten material

Definitions

  • Apparatus has heretofore been proposed for ladling molten metal from a furnace by applying gas under pressure to the surface of the molten metal in an enclosed chamber in the furnace to force the molten metal from the chamber through a discharge tube to a point outside of the furnace.
  • Such apparatus is typified by that more particularly disclosed and claimed in the patent to Edstrand No. 2,816,334.
  • air may be used as the gas.
  • An oxide film will be formed over the surface of the molten metal under these conditions but since there is a minimum of agitation of the metal the film does not grow excessively and normally is not objectionable.
  • Another object is to provide furnace ladling apparatus in which the gas is pumped from a storage tank into the furnace chamber during a discharging operation and is pumped from the furnace chamber into a storage tank during the filling operation.
  • the gas under an intermediate pressure is supplied directly from a storage tank to the furnace through the pump when the pump is stopped.
  • FIGURE 1 is a diagrammatic view with parts of the furnace shown in section of a furnace ladling apparatus embodying the invention.
  • FIGURE 2 is a partial diagram showing an alternative system.
  • the apparatus as shown is adapted to ladle molten metal from a furnace indicated generally at which is provided with a discharge chamber 11 normally open to atmosphere at its top.
  • a discharge chamber 11 normally open to atmosphere at its top.
  • the space above the molten metal in the chamber 11 may be kept filled with an inert atmosphere at a pre determined low pressure approximating atmospheric pressure through connection to a suitable source of such atmosphere not shown.
  • the chamber 11 forms one chamber of a two chamber furnace and may be connected to the other chamber through channels 12.
  • An alternating current coil may thread the channels 12 to induce a flow of current through the metal therein, thereby to heat the metal as is well understood in the art. It will further be understood that the exact type of furnace employed forms no part of the present invention and that the invention may be used in connection with any conventional type of furnace.
  • a crucible 13 For discharging the molten metal from the chamber 11 a crucible 13 is mounted in the chamber and receives metal therefrom through a vertically elongated inlet passage 14 opening at its lower end in the chamber below the level of molten metal therein and opening at its upper end into the upper part of the crucible.
  • a discharge tube 15 communicates at its lower end with the lower part of the crucible and extends upwardly to discharge at a point outside of the furnace body above the normal maximum level of molten metal in the furnace chamber.
  • the top of the crucible is closed by a cover 16 through which a conduit 17 communicates with the interior of the crucible to supply gas under pressure thereto.
  • the crucible may first be subjected to a vacuum to draw molten metal from the furnace chamber through the inlet passage into the crucible to a level above the upper end of the inlet passage.
  • the chamber is then subjected to an intermediate pressure which may be atmospheric or slightly above atmospheric to depress the level in the inlet passage to a point slightly below its upper end as shown in FIGURE 1, leaving the crucible filled to the top of the inlet passage.
  • a higher discharge pressure may be applied to force the metal in the crucible through the discharge conduit 15 Without, however, being high enough to blow past the molten metal in the inlet passage 14.
  • an inert gas is circulated in a closed system to produce the various pressure conditions in the crucible which are desired therein so that the gas may be reused.
  • the exact gas employed will depend upon the metal to be discharged but is selected to be non-reactive with respect to the metal.
  • argon gas is the most satisfactory gas known at the present time although other gases could perhaps be used.
  • aluminum any nonoxidizing gas can be used such, for example, as argon, nitrogen or various combustion gases.
  • a gas may be selected which will not react with the molten metal.
  • the gas is initially supplied from a storage tank 18 containing gas under relatively high pressure. Gas from the tank 18 flows therefrom to a high pressure reservoir or tank 19 through a reducing valve 21 which is adjusted to maintain the gas in the tank 19 under the desired pressure.
  • a relief valve 22 may be connected to the tank 19 to prevent accumulation of excessive pressure therein.
  • the high pressure tank 19 is connected to a low pressure storage tank 23 through a reducing valve 24.
  • the reducing valve 24 may be adjusted to maintain the desired intermediate pressure in the tank 23 which may be atmospheric pressure or a pressure slightly above atmospheric as explained above.
  • the low pressure tank 23 is connected through an outwardly open check valve 25 to one side of a reversible pump 26 which is driven by a reversible electric motor 27.
  • the motor 27 may be supplied with power through a reversing switch 28 by means of which its direction of operation is determined.
  • the other side of the pump is connected to the conduit 17 as shown.
  • the maximum pressure discharged by the pump 26 is determined by a regulator 31 which bypasses the pump to permit flow from the conduit 17 to the side of the pump adjacent to the check valve 25 but which will block flow in the opposite direction.
  • the regulator 31 is adjusted to limit the pressure developed by the pump to the maximum discharge pressure desired in operation of the ladling apparatus so that excessive pressure cannot be developed.
  • the pump is also bypassed by a similar regulator 32 which will pass gas in the direction opposite to the regulator 31 and which functions to limit the maximum degree of vacuum which can be developed in the crucible by the pump.
  • the conduit between the check valve 25 and the pump is also connected through an outwardly open check valve 33 to the'high pressure storage tank 19.
  • the pump In operation of the apparatus with the system filled with inert gas from the tank 18, the pump will first be operated in a direction to create a flow from right to left therethrough to create a vacuum in the crucible. High pressure gas discharged from the pump will flow through the check valve 33 into the high pressure storage tank 19 and the regulator 32 will limit the pressure differential created by the pump so that an excessive vacuum cannot be produced in the crucible. At this time the crucible will be filled with molten metal from the furnace chamber.
  • the pump With the crucible filled to the desired level above the top of the inlet passage the pump will be stopped through control mechanism not shown.
  • the pump while preferably of the positive displacement type, has enough leakage so that the pressure in the crucible will equalize with the pressure in the low pressure storage tank to create within the crucible the desired intermediate pressure.
  • This pressure which may be atmospheric or very slightly above atmospheric will depress the level in the inlet passage 14 to a point below the upper end thereof as shown in the drawing so that the apparatus is ready for a discharge operation.
  • the pump For discharge the pump is reversed to create a flow from left to right. At this time the pump receives gas from the low presure storage tank and forces the gas into the crucible at the relatively high discharge pressure to force molten metal in the crucible out through the discharge tube.
  • the loss of gas will be made up from the supply tank 18 so that the system will be maintained full at all times to the desired pressure values. If there should be seepage into the system which would tend to create an excessive pressure therein the relief valve 22 will open and reduce the pressure to the desired value. It will be seen, therefore, that under normal operating conditions the gas may be reused indefinitely and will be subject to contamination due only to the slight seepage into the system which may occur. If the gas does become contaminated over a period of time due to such seepage, the system may be purged and refilled with fresh gas although this should be necessary only at extremely long intervals.
  • FIGURE 2 illustrates a simplified system which may be used under certain conditions for the same purposes as the system of FIGURE 1.
  • parts in FIGURE 2 corresponding to like parts in FIGURE 1 have been indicated by the same reference numerals.
  • the tank is connected through a reducing valve 24 and a three-way valve 35 to the left side of the pump 26 and the right side of the pump 26 communicates with a fourway valve 36.
  • a conduit 37 connects the valves 35 and 36 and a second conduit 38 connects the valve 36 to the tank 19 with the conduit 17 also communicating with the valve 36.
  • the pump 26 is not reversible and functions at all times to create a flow from left to right therethrough as indicated.
  • valves 35 and 36 are adjusted to the position shown in which the conduit 17 communicates through the valves with the inlet side of the pump and the outlet side of the pump is connected through the valve 36 and conduit 38 to the storage tank 19. Under these conditions the pump will produce a vacuum in the crucible to fill it with molten metal.
  • valve 35 is turned through clockwise to connect the inlet side of the pump through the regulator 24 to the storage tank 19.
  • valve 36 is turned through 45 counterclockwise to connect the outlet of the pump to the conduit 17, and the pump is stopped.
  • the crucible will be subjected to an intermediate pressure determined by the setting of the regulator 24 due to leakage through the stopped pump to create a condition in the crucible such as that illustrated in FIGURE 1.
  • the crucible is now ready for a discharge operation. Without re-adjusting the valves the pump is now started up to draw gas from the storage tank 19 through the reducing valve 24 and to discharge the gas through the valve 36 and the conduit 17 into the crucible to produce the desired relatively high discharge pressure. At this time the molten metal in the crucible will be forced therefrom through the discharge tube 15 and at the completion of the discharging operation the apparatus is ready for a further cycle.
  • Furnace ladling apparatus comprising means defining a chamber adapted to hold molten metal and closed at its top, the chamber having an inlet for molten metal, a discharge tube communicating with the lower part of the chamber and discharging outside of the chamber above the maximum level of molten metal therein, a first storage tank to hold a gas under relatively high pressure which is non-reactive with the molten metal, a second storage tank connected to the first storage tank to receive gas therefrom, and including regulating means to maintain a lower pressure in the second storage tank than in the first storage tank, pump means connected to the storage tanks and the chamber, and control means to establish one condition in which the inlet of the pump means communicates with the chamber and the outlet with the first storage tank and a second condition in which the inlet of the pump means communicates with the second storage tank and the outlet with the chamber.
  • the pump means is a reversible pump having one side thereof connected to the storage tanks respectively through oppositely opening check valves.

Landscapes

  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Manufacture And Refinement Of Metals (AREA)
  • Casting Support Devices, Ladles, And Melt Control Thereby (AREA)

Description

Jan. 18, 1966 G. w. HOLZ ETAL 3,229,337
FURNACE LADLING APPARATUS Filed Sept. 24, 1962 Invenfors George W Holz Hugh E. Pollard United States Patent Oflice 3,229,337 Patented Jan. 18, 1966 3,229,337 FURNACE LADLING APPARATUS George William Holz, Chicago, and Hugh E. Pollard, Franklin Park, 111., assignors to Lindberg Engineering Co., a corporation of Illinois Filed Sept. 24, 1962, Ser. No. 225,706 3 Claims. (Cl. 2279) This invention relates to furnace ladling apparatus and more particularly to apparatus for discharging measured shots or charges of molten metal from a furnace chamber.
Apparatus has heretofore been proposed for ladling molten metal from a furnace by applying gas under pressure to the surface of the molten metal in an enclosed chamber in the furnace to force the molten metal from the chamber through a discharge tube to a point outside of the furnace. Such apparatus is typified by that more particularly disclosed and claimed in the patent to Edstrand No. 2,816,334. When the metal is not highly reactive such as aluminum or similar metals or alloys, air may be used as the gas. An oxide film will be formed over the surface of the molten metal under these conditions but since there is a minimum of agitation of the metal the film does not grow excessively and normally is not objectionable.
For use with highly reactive molten metals such as magnesium or in cases where an extremely high degree of purity is required air or other gas which reacts with the molten metal cannot be used. Due to the expense of non-reactive gases and predisposition also to contamination of the atmosphere it is not practical to use a non-reactive gas in apparatus which vents the gas or wastes it to atmosphere.
It is accordingly one of the objects of the present invention to provide furnace ladling apparatus in which a non-reactive gas is employed and is circulated in a closed system so that it may be used indefinitely with a minimum of waste or contamination.
Another object is to provide furnace ladling apparatus in which the gas is pumped from a storage tank into the furnace chamber during a discharging operation and is pumped from the furnace chamber into a storage tank during the filling operation.
According to a feature of the invention the gas under an intermediate pressure is supplied directly from a storage tank to the furnace through the pump when the pump is stopped.
The above and other objects and features of the invention will be more readily apparent from the following description when read in connection with the accompanying drawing in which:
FIGURE 1 is a diagrammatic view with parts of the furnace shown in section of a furnace ladling apparatus embodying the invention; and
FIGURE 2 is a partial diagram showing an alternative system.
The apparatus as shown is adapted to ladle molten metal from a furnace indicated generally at which is provided with a discharge chamber 11 normally open to atmosphere at its top. In the case of highly reactive metals the space above the molten metal in the chamber 11 may be kept filled with an inert atmosphere at a pre determined low pressure approximating atmospheric pressure through connection to a suitable source of such atmosphere not shown. In the furnace illustrated the chamber 11 forms one chamber of a two chamber furnace and may be connected to the other chamber through channels 12. An alternating current coil may thread the channels 12 to induce a flow of current through the metal therein, thereby to heat the metal as is well understood in the art. It will further be understood that the exact type of furnace employed forms no part of the present invention and that the invention may be used in connection with any conventional type of furnace.
For discharging the molten metal from the chamber 11 a crucible 13 is mounted in the chamber and receives metal therefrom through a vertically elongated inlet passage 14 opening at its lower end in the chamber below the level of molten metal therein and opening at its upper end into the upper part of the crucible. A discharge tube 15 communicates at its lower end with the lower part of the crucible and extends upwardly to discharge at a point outside of the furnace body above the normal maximum level of molten metal in the furnace chamber. The top of the crucible is closed by a cover 16 through which a conduit 17 communicates with the interior of the crucible to supply gas under pressure thereto.
In the normal operation of the furnace the crucible may first be subjected to a vacuum to draw molten metal from the furnace chamber through the inlet passage into the crucible to a level above the upper end of the inlet passage. The chamber is then subjected to an intermediate pressure which may be atmospheric or slightly above atmospheric to depress the level in the inlet passage to a point slightly below its upper end as shown in FIGURE 1, leaving the crucible filled to the top of the inlet passage. Thereafter a higher discharge pressure may be applied to force the metal in the crucible through the discharge conduit 15 Without, however, being high enough to blow past the molten metal in the inlet passage 14.
According to the present invention an inert gas is circulated in a closed system to produce the various pressure conditions in the crucible which are desired therein so that the gas may be reused. The exact gas employed will depend upon the metal to be discharged but is selected to be non-reactive with respect to the metal. In the case of magnesium, argon gas is the most satisfactory gas known at the present time although other gases could perhaps be used. In the case of aluminum, any nonoxidizing gas can be used such, for example, as argon, nitrogen or various combustion gases. In the case of other metals a gas may be selected which will not react with the molten metal.
As shown in FIGURE 1 the gas is initially supplied from a storage tank 18 containing gas under relatively high pressure. Gas from the tank 18 flows therefrom to a high pressure reservoir or tank 19 through a reducing valve 21 which is adjusted to maintain the gas in the tank 19 under the desired pressure. A relief valve 22 may be connected to the tank 19 to prevent accumulation of excessive pressure therein. The high pressure tank 19 is connected to a low pressure storage tank 23 through a reducing valve 24. The reducing valve 24 may be adjusted to maintain the desired intermediate pressure in the tank 23 which may be atmospheric pressure or a pressure slightly above atmospheric as explained above. The low pressure tank 23 is connected through an outwardly open check valve 25 to one side of a reversible pump 26 which is driven by a reversible electric motor 27. The motor 27 may be supplied with power through a reversing switch 28 by means of which its direction of operation is determined. The other side of the pump is connected to the conduit 17 as shown.
The maximum pressure discharged by the pump 26 is determined by a regulator 31 which bypasses the pump to permit flow from the conduit 17 to the side of the pump adjacent to the check valve 25 but which will block flow in the opposite direction. The regulator 31 is adjusted to limit the pressure developed by the pump to the maximum discharge pressure desired in operation of the ladling apparatus so that excessive pressure cannot be developed. The pump is also bypassed by a similar regulator 32 which will pass gas in the direction opposite to the regulator 31 and which functions to limit the maximum degree of vacuum which can be developed in the crucible by the pump. The conduit between the check valve 25 and the pump is also connected through an outwardly open check valve 33 to the'high pressure storage tank 19.
In operation of the apparatus with the system filled with inert gas from the tank 18, the pump will first be operated in a direction to create a flow from right to left therethrough to create a vacuum in the crucible. High pressure gas discharged from the pump will flow through the check valve 33 into the high pressure storage tank 19 and the regulator 32 will limit the pressure differential created by the pump so that an excessive vacuum cannot be produced in the crucible. At this time the crucible will be filled with molten metal from the furnace chamber.
With the crucible filled to the desired level above the top of the inlet passage the pump will be stopped through control mechanism not shown. When stopped the pump, while preferably of the positive displacement type, has enough leakage so that the pressure in the crucible will equalize with the pressure in the low pressure storage tank to create within the crucible the desired intermediate pressure. This pressure which may be atmospheric or very slightly above atmospheric will depress the level in the inlet passage 14 to a point below the upper end thereof as shown in the drawing so that the apparatus is ready for a discharge operation.
For discharge the pump is reversed to create a flow from left to right. At this time the pump receives gas from the low presure storage tank and forces the gas into the crucible at the relatively high discharge pressure to force molten metal in the crucible out through the discharge tube.
In the event of gas leakage from the system, as for example by seeping through the crucible or the joints therein, the loss of gas will be made up from the supply tank 18 so that the system will be maintained full at all times to the desired pressure values. If there should be seepage into the system which would tend to create an excessive pressure therein the relief valve 22 will open and reduce the pressure to the desired value. It will be seen, therefore, that under normal operating conditions the gas may be reused indefinitely and will be subject to contamination due only to the slight seepage into the system which may occur. If the gas does become contaminated over a period of time due to such seepage, the system may be purged and refilled with fresh gas although this should be necessary only at extremely long intervals.
FIGURE 2 illustrates a simplified system which may be used under certain conditions for the same purposes as the system of FIGURE 1. For the purposes of brevity of description parts in FIGURE 2 corresponding to like parts in FIGURE 1 have been indicated by the same reference numerals. In the construction shown in FIGURE 2 only one storage tank 19 is employed which is connected to the supply tank 18 through a reducing valve 21 and to a relief valve 22 so that the desired high pressure will be maintained in the tank. The tank is connected through a reducing valve 24 and a three-way valve 35 to the left side of the pump 26 and the right side of the pump 26 communicates with a fourway valve 36. A conduit 37 connects the valves 35 and 36 and a second conduit 38 connects the valve 36 to the tank 19 with the conduit 17 also communicating with the valve 36. In this case the pump 26 is not reversible and functions at all times to create a flow from left to right therethrough as indicated.
To produce a vacuum in the crucible the valves 35 and 36 are adjusted to the position shown in which the conduit 17 communicates through the valves with the inlet side of the pump and the outlet side of the pump is connected through the valve 36 and conduit 38 to the storage tank 19. Under these conditions the pump will produce a vacuum in the crucible to fill it with molten metal.
At the completion of the filling operation the valve 35 is turned through clockwise to connect the inlet side of the pump through the regulator 24 to the storage tank 19. At the same time the valve 36 is turned through 45 counterclockwise to connect the outlet of the pump to the conduit 17, and the pump is stopped. At this time the crucible will be subjected to an intermediate pressure determined by the setting of the regulator 24 due to leakage through the stopped pump to create a condition in the crucible such as that illustrated in FIGURE 1. The crucible is now ready for a discharge operation. Without re-adjusting the valves the pump is now started up to draw gas from the storage tank 19 through the reducing valve 24 and to discharge the gas through the valve 36 and the conduit 17 into the crucible to produce the desired relatively high discharge pressure. At this time the molten metal in the crucible will be forced therefrom through the discharge tube 15 and at the completion of the discharging operation the apparatus is ready for a further cycle.
While two embodiments of the invention have been shown and described in detail, it will be understood that these are illustrative only and are not to be taken as a definition of the scope of the invention, reference being had for this purpose to the appended claims.
What is claimed is:
1. Furnace ladling apparatus comprising means defining a chamber adapted to hold molten metal and closed at its top, the chamber having an inlet for molten metal, a discharge tube communicating with the lower part of the chamber and discharging outside of the chamber above the maximum level of molten metal therein, a first storage tank to hold a gas under relatively high pressure which is non-reactive with the molten metal, a second storage tank connected to the first storage tank to receive gas therefrom, and including regulating means to maintain a lower pressure in the second storage tank than in the first storage tank, pump means connected to the storage tanks and the chamber, and control means to establish one condition in which the inlet of the pump means communicates with the chamber and the outlet with the first storage tank and a second condition in which the inlet of the pump means communicates with the second storage tank and the outlet with the chamber.
2. The apparatus of claim 1 in which the pump means is a reversible pump having one side thereof connected to the storage tanks respectively through oppositely opening check valves.
3. The apparatus of claim 1 in which the second storage tank communicates with the chamber through the pump means when it is stopped to supply an intermediate pressure to the chamber.
References Cited by the Examiner UNITED STATES PATENTS 2,149,633 3/ 1939 Schnoor 222399 2,816,334 12/ 1957 Edstrand 2279 2,819,059 1/1958 Breymeier 26638 2,846,740 8/ 1958 Edstrand 2279 3,050,794 8/ 1962 Holz 2279 3,05 8,180 10/ 1962 Port et al 2279 I. SPENCER OVERHOLSER, Primary Examiner.
MARCUS U. LYONS, WILLIAM J. STEPHENSON,
Examiners.

Claims (1)

1. FURNACE LADLING APPARATUS COMPRISING MEANS DEFINING A CHAMBER ADAPTED TO HOLD MOLTEN METAL AND CLOSED AT ITS TOP, THE CHAMBER HAVING AN INLET FOR MOLTEN METAL, A DISCHARGE TUBE COMMUNICATING WITH THE LOWER PART OF THE CHAMBER AND DISCHARGING OUTSIDE OF THE CHAMBER ABOVE THE MAXIMUM LEVEL OF MOLTEN METAL THEREIN, A FIRST STORAGE TANK TO HOLD A GAS UNDER RELATIVELY HIGH PRESSURE WHICH IS NON-REATIVE WITIH THE MOLTEN METAL, A SECOND STORAGE TANK CONNECTED TO THE FIRST STORAGE TANK TO RECEIVE GAS THEREFROM, AND INCLUDING REGULATING MEANS TO MAINTAIN A LOWER PRESSURES IN THE SECOND STORAGE TANK THAN IN THE FIRST STORAGE TANK, MEANS CONNECTED TO THE STORAGE TANKS AND THE CHAMBER, AND CONTROL MEANS TO ESTABLISH ONE CONDITION IN WHICH THE INLET OF THE PUMP MEANS COMMUNICATES WITH THE CHAMBER AND THE OUTLET WITH THE FIRST STORAGE TANK AND A SECOND CONDITION IN WHICH THE INLET OF THE PUMP MEANS COMMUNICATES WITH THE SECOND STORAGE TANK AND THE OUTLET WITH THE CHAMBER.
US225706A 1962-09-24 1962-09-24 Furnace ladling apparatus Expired - Lifetime US3229337A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US225706A US3229337A (en) 1962-09-24 1962-09-24 Furnace ladling apparatus

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US225706A US3229337A (en) 1962-09-24 1962-09-24 Furnace ladling apparatus

Publications (1)

Publication Number Publication Date
US3229337A true US3229337A (en) 1966-01-18

Family

ID=22845906

Family Applications (1)

Application Number Title Priority Date Filing Date
US225706A Expired - Lifetime US3229337A (en) 1962-09-24 1962-09-24 Furnace ladling apparatus

Country Status (1)

Country Link
US (1) US3229337A (en)

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3331429A (en) * 1965-06-08 1967-07-18 Imp Eastman Corp Pneumatic pressure casting apparatus
US3347427A (en) * 1965-11-30 1967-10-17 Campbell James S Pressure pour apparatus
US3445041A (en) * 1966-10-05 1969-05-20 Campbell Auto Pour Eng Liquid dispensing assembly with improved filling means
US3504825A (en) * 1966-08-15 1970-04-07 Gen Motors Corp Pneumatic control of pressure pouring ladle
US5146974A (en) * 1990-10-02 1992-09-15 Globe-Union Inc. Lead pouring system

Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2149633A (en) * 1936-03-30 1939-03-07 Raymond D Schnoor Draft apparatus
US2816334A (en) * 1956-09-24 1957-12-17 Lindberg Eng Co Automatic ladling control for metal melting furnace
US2819059A (en) * 1954-06-25 1958-01-07 Union Carbide Corp Apparatus for transferring highly reactive molten metals
US2846740A (en) * 1956-09-17 1958-08-12 Lindberg Eng Co Furnace ladling apparatus
US3050794A (en) * 1959-09-08 1962-08-28 Lindberg Eng Co Furnace ladling apparatus
US3058180A (en) * 1961-10-11 1962-10-16 Modern Equipment Co Apparatus for pouring molten metal

Patent Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2149633A (en) * 1936-03-30 1939-03-07 Raymond D Schnoor Draft apparatus
US2819059A (en) * 1954-06-25 1958-01-07 Union Carbide Corp Apparatus for transferring highly reactive molten metals
US2846740A (en) * 1956-09-17 1958-08-12 Lindberg Eng Co Furnace ladling apparatus
US2816334A (en) * 1956-09-24 1957-12-17 Lindberg Eng Co Automatic ladling control for metal melting furnace
US3050794A (en) * 1959-09-08 1962-08-28 Lindberg Eng Co Furnace ladling apparatus
US3058180A (en) * 1961-10-11 1962-10-16 Modern Equipment Co Apparatus for pouring molten metal

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3331429A (en) * 1965-06-08 1967-07-18 Imp Eastman Corp Pneumatic pressure casting apparatus
US3347427A (en) * 1965-11-30 1967-10-17 Campbell James S Pressure pour apparatus
US3504825A (en) * 1966-08-15 1970-04-07 Gen Motors Corp Pneumatic control of pressure pouring ladle
US3445041A (en) * 1966-10-05 1969-05-20 Campbell Auto Pour Eng Liquid dispensing assembly with improved filling means
US5146974A (en) * 1990-10-02 1992-09-15 Globe-Union Inc. Lead pouring system

Similar Documents

Publication Publication Date Title
US3229337A (en) Furnace ladling apparatus
EP0967034A1 (en) Dispensing apparatus and method
US3310850A (en) Method and apparatus for degassing and casting metals in a vacuum
US3116999A (en) Method and apparatus for degassing liquids in a vacuum
US3700429A (en) Method of controlling vacuum decarburization
GB917298A (en) Improvements relating to furnace ladling apparatus
US3550924A (en) Mechanism for controlling flow of liquid to a vacuum-treating vessel
US2929704A (en) Methods of and apparatus for degasifying metals
US3126906A (en) Pressure stabilizing apparatus
US3291596A (en) Method and apparatus for purging molten metal of gaseous impurities
US3279001A (en) Pouring apparatus with radioactive means for determining molten metal level in riser conduit
US3410332A (en) Method and apparatus for casting metals in a controlled atmosphere
US6779588B1 (en) Method for filling a mold
US3214153A (en) Cooling water supply system
US3729118A (en) Device for controlling the level of liquid metal in a casting container
SU553921A3 (en) Installation for low pressure casting
US5031805A (en) Processes and device for dosing free-flowing media
US3347427A (en) Pressure pour apparatus
KR960007630B1 (en) Method and device of low pressure casting
US3211545A (en) Process and apparatus for vacuum degassing of metal
US3340925A (en) Automatic level control for metal casting
US4566859A (en) Method for carrying liquid metal by two series-connected electric magnet pumps
US3178782A (en) Vacuum die casting of molten metals
JP3727444B2 (en) Differential pressure casting apparatus and differential pressure casting method
EP0040352B1 (en) A molten metal dispensing apparatus