JPH04228257A - Feeding launder device for molten metal and launder nozzle - Google Patents

Abstract

PURPOSE: To enhance the perfectness of a casting by removably mounting a nozzle and filter assembly which includes a nozzle for supplying molten metal from a launder to a casting mold and has a filter for filtering the molten metal flowing through the nozzle at the launder. CONSTITUTION: This launder system 16 is used to supply the molten metal from a source for the molten metal 14 to the casting mold or secondary stage. The system includes the nozzle 22 arranged to supply the molten metal from the launder to the casting mold or the secondary stage and has the filter 26 arranging within the nozzle in order to filter the molten metal flowing through the nozzle. The assembly of the nozzle and the filter is removably mounted at the launder. As a result, the launder system which allows the use of the launder >=2 times in order to build the filter by taking the advantage of ceramic linings may be obtd.

Description

[Detailed description of the invention]

[0001] The present invention relates to a launder device (
launder system), in particular launder nozzles.

It is current practice to melt metal in a crucible and feed the molten metal from the crucible to one or more molds or secondary steps. Molten metal is fed along a launder that has one or more channels for connecting the crucible to the mold or secondary process.

[0003]It is known to incorporate devices to reduce or eliminate the amount of inclusions present in the molten metal passing through the launder in order to clean the molten metal and improve the integrity of the finished casting. .

One way to do this is to provide one or more dams or weirs within the launder to capture the intervening material. However, some inclusions may still be carried all the way to the mold or secondary process.

Another way to do this is to provide a fixed filter within the launder. This is more effective than a dam for cleaning molten metal. However, the provision of a filter within the launder can cause blockages, which may result in the launder being scrapped and rebuilt.

In some launders, a ceramic lining is bonded to the launder and is typically replaced after each casting operation.

[0007] Certain crucibles are provided with a ceramic lining, and it is customary for such crucibles to have a flushing melt that cleans the surface of the ceramic lining and removes any loose debris. Thus, it can be seen that the launders used today waste their ceramic lining after only one use.

The object of the invention is to provide a laundering device which takes advantage of the ceramic lining and allows the launder to be used more than once to incorporate a filter.

Accordingly, the present invention provides a launder device for supplying molten metal from a molten metal source to a mold or a secondary process, and which, during operation, supplies molten metal from the launder to the mold or secondary process.
The nozzle and filter assembly is removable to the launder, including a nozzle configured to supply molten metal to the next process and a filter configured within the nozzle to filter the molten metal flowing through the nozzle. Provide installed launder equipment.

[0010] A replacement device can be arranged for removing the first used nozzle and filter assembly from the launder and installing a second, unused nozzle and filter assembly on the launder.

Preferably, the filter is a reticulated foam filter.

[0012] The launder and the nozzle have a mating surface, and the mating surface can have a sealing device to prevent leakage of molten metal.

[0013] The sealing device may include mating valleys and peaks on the mating surfaces.

[0014] The sealing device may include a refractory packing on either of the mating surfaces.

[0015] The launder can have a ceramic lined channel.

[0016] The filter can be integral with the nozzle.

A heating device may be provided for heating the nozzle filter assembly. Preferably, the heating device includes at least one induction coil. Preferably, an induction ring is within the induction coil and disposed around the nozzle.

The filter is preferably a reticulated foam filter.

[0019] The filter can be integral with the nozzle.

The invention will now be explained in more detail by way of example with reference to the accompanying drawings, in which: FIG.

In FIG. 1, a crucible 10 containing molten metal 14 is shown. The crucible 10 has a lining 12 of ceramic material. The crucible 10 is arranged to supply molten metal to one or more molds or secondary steps via a laundering device 16. The secondary step involves coating the article or depositing the atomized particles on a former.
It can be an atomization process to make products or metal powders.

The launder device 16 includes one or more channel members 18 having a lining 20 of ceramic material. The launder device 16 includes one or more nozzles 2 that supply molten metal from a launder channel member 18 to a mold or a secondary process.
Including 2.

Each nozzle 22 has a ceramic lining 24 and is provided with a filter 26 disposed within the nozzle 22 . A filter 26 is disposed for filtering the molten metal as it flows from the launder channel member 18 to the mold or secondary process through the nozzle 22.

The nozzle 22 and filter 26 assembly is removably attached to the launder channel member 18 by suitable equipment so that after the nozzle/filter assembly has been used, it can be replaced with a new nozzle/filter assembly. do.

[0025] Providing a removable nozzle and filter assembly allows for effective cleaning of molten metal without the disadvantage of increasing the likelihood of blockage. This reduces the scrapping rate of the laundering device and allows the laundering device to be used multiple times to take maximum advantage of the ceramic lining.

An induction heating coil 38 is provided coaxially around the nozzle 22 and filter 26 assembly to directly heat the molten metal as it flows through the nozzle 22 and filter 26 assembly. , reducing the possibility of metal solidification within the nozzle 22 or filter 26. It may be desirable to use several induction heating coils arranged coaxially around the nozzle filter assembly, particularly induction coils of different diameters corresponding to portions of the nozzle 22 having different outer diameters. A conductive ring 40, or susceptor, is coaxially within the induction heating coil 38.
Coaxially arranged around the nozzle 22 and filter 26 assembly. Inductive ring 40 is heated by induction coil 38 and conductive ring 40 then dissipates heat to heat the nozzle 22 and filter 26 assembly. The induction coil shared with the susceptor has a nozzle/filter assembly.
While they can be used to preheat molten metal before it flows through, induction coils alone cannot preheat the nozzle filter assembly. Conductive ring 40 is a graphite ring in this example. Although in FIG. 1 conductive ring 40 contacts nozzle 22, ring 40 can be spaced from nozzle 22.

Although induction heating coils are shown, radiant heaters, such as electrical resistance heaters, may also be used to heat the nozzle filter assembly. Radiant heaters may also be used to preheat the nozzle filter assembly before the molten metal flows through it to eliminate or reduce the possibility that the molten metal will solidify within the nozzle filter assembly. .

The nozzle 22 is fabricated using any suitable ceramic molding technique, such as isostatic pressing, or injection molding followed by sintering, although other suitable methods may also be used, such as shell molding. Although the filter 26 is a reticulated foam filter, other suitable filters may be used.

A mechanism may be provided to allow quick exchange of the nozzle and filter assembly for removing the used nozzle and filter assembly and installing a new, unused nozzle and filter assembly.

[0030] The quick exchange mechanism can include, for example, an arm having first and second ends. A first end of the arm is pivotally mounted about a vertical axis and a second end releasably retains a nozzle and filter assembly. The arm is simply rotated about its pivot axis between the first and second positions. in a first position, a new, unused nozzle and filter assembly is attached to the second end of the arm;
The arm is then rotated to a second position to place and use a new nozzle and filter assembly on the underside of the launder. The arm is then rotated back to the first position to remove the used nozzle and filter assembly and allow use of another new nozzle and filter assembly.

The quick exchange mechanism has a first end pivotally mounted about the same vertical axis and a second end with each arm releasably retaining a nozzle filter assembly. Of course, it is possible to have

[0032] The quick change mechanism could alternatively have a reciprocating arm.

A portion of the launder channel member 18 and the nozzle 22 are shown in FIG. Engages with the ridges 30 to form a seal.

The upper end of the nozzle 22 fits into the recess 19 on the lower side of the launder 18. Nozzle 22 is launder 1
8, it is pushed into the recess 19, and for removal it is pulled out of the recess 19. During use, the nozzle 22 is held fixed by the clamping action between the launder 18 and the arm of the exchange mechanism.

An alternative seal is shown in FIG. 3 in which a refractory packing 36 is disposed between the mating surfaces of the launder channel member 18 and the nozzle 22.

2 and 3 also show an alternative position for the filter 26, the nozzle 22 in FIG. 3 being entirely ceramic and having a smooth conical shape to reduce the possibility of cracking due to thermal shock. ing.

Although the filter is shown as a separate element from the nozzle, it can alternatively be formed integrally with the nozzle.

[Brief explanation of the drawing]

1 is a longitudinal section through a crucible for molten metal and a laundering device according to the invention; FIG.

FIG. 2 is an enlarged sectional view of a portion of the launder device shown in FIG. 1;

3 is an enlarged cross-sectional view of an alternative embodiment of the portion of the launder device shown in FIG. 1; FIG.

[Explanation of symbols]

10: Crucible 14: Molten metal 16: Launder device 18: Channel member 20: Lining 22: Nozzle 26: Filter 28: Valley 30: Mountain 32: Mountain 34: Valley 36: Packing 38: Induction coil 40: Conductive ring

Claims (17)

[Claims] Claims: 1. A laundering apparatus for supplying molten metal from a source of molten metal to a mold or a secondary process; in operation, the launder apparatus is arranged to supply molten metal from the launder to a mold or a secondary process; a nozzle, the nozzle having a filter disposed within the nozzle for filtering molten metal flowing through the nozzle, and the nozzle and filter assembly being removably attached to the launder; launder device. 2. The laundering apparatus of claim 1, further comprising a heating device for heating the nozzle and filter assembly. 3. The launder device of claim 2, wherein the heating device includes at least one induction heating coil. 4. The laundering device of claim 3, wherein an electrically conductive ring is disposed within the induction coil and around the nozzle. 5. The laundering apparatus of claim 2, wherein the heating device includes at least one electrical resistance heater. 6. A replacement device is provided for removing the first used nozzle and filter assembly and installing a second new, unused nozzle and filter assembly on the launder. 1 launder device. 7. The exchange device includes an arm having a first end and a second end, the first end of the arm being pivotally mounted about an axis, and the second end disengaging the nozzle filter assembly. The arm is adapted to be freely held and rotated to remove a first used nozzle and filter assembly from the launder or to install a second unused nozzle and filter assembly to the launder. Claim 6
launder device. 8. The exchange device includes a plurality of arms, each arm having a first end and a second end, the first end of the arm being pivotally mounted about a common axis, and the first end of the arm being pivotally mounted about a common axis; is arranged to releasably retain the nozzle filter assembly;
One of the arms removes the first used nozzle and filter assembly from the launder, and the other arm removes the second used nozzle and filter assembly from the launder.
7. The laundering apparatus of claim 6, wherein said arm is rotated to load an unused nozzle and filter assembly into the launder. 9. The laundering apparatus of claim 1, wherein the filter is a reticulated foam filter. 10. The laundering apparatus of claim 1, wherein the launder and nozzle have a mating surface, and the mating surface has a seal to prevent leakage of molten metal. 11. The laundering device of claim 10, wherein the seal includes interlocking valleys and peaks on the mating surface. 12. The launder apparatus of claim 10, wherein said sealing device is a fire-resistant packing attached to either of said mating surfaces. 13. The laundering apparatus of claim 1, wherein the launder has a ceramic lined channel. 14. The launder device of claim 1, wherein the filter is integral with the nozzle. 15. A launder nozzle including a filter arranged to filter molten metal flowing through the nozzle during use. 16. The launder nozzle of claim 15, wherein the filter is a reticulated foam filter. 17. The launder nozzle of claim 15, wherein the filter is integral with the nozzle.