EP0965403A1 - Decomposition, accumulation and removal of remaining alumina in liquid aluminium-alloys in casting troughs or channels or the like before entry into moulds or mould-aggregates - Google Patents

Abstract

A casting trough or channel is covered over so that a flowing aluminum alloy in it is not directly exposed to atmospheric air. A gas mixture consisting of nitrogen, chlorine and possibly fluorine is continuously blown through the bottom flow area of the alloy, while aluminum oxide residues emerge on the surface of the alloy.

Description

The invention relates to disassembly, accumulation and elimination remaining residual substances of aluminum oxide for liquid aluminum alloys that are used in chill molds or chill mold machines be shed.

The production of aluminum castings to be anodized later is caused by disturbing side effects inform of aluminum oxides accompanied.

The development has not stopped in the foundries in recent years; not even in the permanent mold foundries, where aluminum alloys are cast.
The fact cannot and must not be overlooked that all possible technical changes can occur, but nothing has changed in metallurgical processes in the past, nothing will change in the future, but nothing at all.
Possibilities for change in this area will always remain illusions.

The fact that aluminum or aluminum alloys have a strong affinity for oxygen - especially in the liquid state - was and is found in the past.
Nothing will change in the future, not even through actions or manipulations of any kind.

This affinity is particularly disruptive in later to anodized castings. This is particularly evident pronounced in the sector of aluminum hardware.

Schmelzen im Schmelzofen, in Warmhalteöfen, praktisch in jedem Zustand, in dem flüssiges Aluminium bzw. Alu-Legierungen bewegt werden, also auch beim Vergiessen.

Oxygen, including oxygen from the atmospheric air, combines particularly well with liquid aluminum or aluminum alloys in every phase to form aluminum oxide Al ₂ O ₃

Melting in the melting furnace, in holding furnaces, practically in any condition in which liquid aluminum or aluminum alloys are moved, i.e. also during casting.

Aluminum oxide is heavier than aluminum, it should practically sink to the bottom of the crucible in the crucible, especially in the holding pot.
Unfortunately, this does not happen because the weight difference between aluminum and aluminum oxide is effectively small. The aluminum oxide practically hovers in the melt as so-called oxide skins, especially due to the fact that there is a certain movement in each crucible.

Pre-melting aluminum alloys in induction furnaces is favored the formation of aluminum oxide is particularly pronounced because of this Premelting type is a strong one with liquid aluminum alloys Circulation caused and reminiscent of "boiling" aluminum alloy.

A melt contaminated by aluminum oxides can only be cleaned by chlorine or fluorine by introducing chlorine and fluorine gases into the lower part of the crucible.
For the most part, the gases emerge from the metal surface as chemically unchanged and mix with the atmospheric circulating air.
These cleaning gases are extremely harmful to health and may only be added to the circulating air if they are disposed of.

Cleaning salts on the market and also used do not remove aluminum oxides unless they release chlorine or additionally fluorine gas.
The exhaust gases released must also be disposed of.
The dross that forms mainly consists of rock salt and aluminum alloy components.

The object of the invention is now a construction arrangement to create that prevents aluminum oxides when casting aluminum alloys into castings get a mold.

This object is achieved by the characterizing part of claim 1.
Refinements are the subject of claims 2 to 10.

In the characterizing part of claim 1 of the invention provided that gutters, pouring channels or the like Lead mold or mold machine inlets covered are, and a gas mixture of nitrogen and predominantly Chlorine constantly flowing through the lower flow area Aluminum alloy is blown.

According to claim 2, the gutter or the pouring channel from the lower and upper part, whereby liquid metal exclusively in the lower part of the gutter or the pouring channel flows into the mold inlet until it has an influence.

The gutter or the pouring channel is made according to claim 3 constantly heated so that the flowing metal is the selected one Pouring temperature not below.

A gray cast alloy should contain a few percent chromium contain stabilization and heat resistance, as in Claim 4 specified.

According to claim 5, the gas mixture penetrates in a straight line or staggered through the lower part and penetrates the liquid flowing metal, a relatively small residual constituent being formed as real dross and, according to claim 6, being held on a braking part web of the pouring channel or the pouring channel and settling.
The liquid metal in the lower part of the pouring channel or pouring channel continues to flow freely in the bottom part of the pouring channel or pouring channel in the oxide-free state.

According to claims 7 and 8, the gutter and the pouring channel provided with insulation and can be swung out so that an easy replacement can take place.

In the upper part of the metal flow there is a build-up on a partial brake bridge a portion of itch that occurs at certain time intervals is to be scraped.

A heated container at one end of the launder or the pouring channel takes a certain amount of liquid Metal as described in claim 10.

Further features and details emerge from the precise wording of the claims and drawings, to which, however, the invention is not restricted.
It is entirely possible that the claims, the description and the explanation of the drawings result in characteristics and features that may be significant to the invention for themselves or in various construction combinations.

The invention is explained in more detail based on the drawings. However, reference is made to the fact that the drawings are shown in simplified form.
However, more detailed elaborations do not change the inventive idea.

Fig.1

eine Aufsichtszeichnung des Unterteils der Giessrinne oder des Giesskanals,

Fig.2

eine Teilansichtszeichnung gemäss Fig.1 um 90° geschwenkt,

Fig.3

eine Teilquerschnittszeichnung gemäss Schnitt A-A (Fig.1),

Fig.4

eine Teilansichtszeichnung des Oberteils der Giessrinne odes des Giesskanals,

Fig.5

eine Querschnittszeichnung gemäss Schnitt B-B (Fig.4)

Fig.6

eine Teilansichtszeichnung der Giessrinne oder des Giesskanals mit Unter- und Oberteil,

Fig.7

eine Querschnittszeichnung gemäss Schnitt C-C (Fig.6)

So show

Fig. 1

a supervisory drawing of the lower part of the pouring channel or the pouring channel,

Fig. 2

1 a partial view drawing according to FIG. 1 pivoted through 90 °,

Fig. 3

a partial cross-sectional drawing according to section AA (Fig.1),

Fig. 4

a partial view drawing of the upper part of the pouring channel or the pouring channel,

Fig. 5

a cross-sectional drawing according to section BB (Fig.4)

Fig. 6

a partial view drawing of the pouring channel or the pouring channel with the lower and upper part,

Fig. 7

a cross-sectional drawing according to section CC (Fig. 6)

In Fig. 1 the complete lower part is shown as a pouring channel or channel (1) in a simplified version.
The pouring channel or the pouring channel has a cover frame (2) Fig. 1, 2 on which the upper part (11) Fig. 6, 7 rests.
The bottom (3) Fig. 1, 2 is provided with inlet connection (4) Fig. 1 and through holes (5) Fig. 1.
A mixed gas is continuously blown in through these nozzles (4) or their through bores (5), Fig. 1, 3.
The sockets are designed so that supply lines can be securely attached.

The pouring channel (1) Fig. 1 or the pouring channel has at one end a container (6) Fig. 3 that is particularly enlarged in height, which is moved from the pouring channel (1) by a movable slide (7) Fig.1 or the pouring channel can be separated.
The movable slide (7) is expediently guided in the sides (8) of the pouring channel or the pouring channel; expediently also in the bottom of the pouring channel (1) or the pouring channel.

Immerse into the gutter (1) Fig. 1,2 or the pouring channel when placing or folding the upper part of the in the Drawing Fig.1 as a dash-dotted brake section (13) a.

Fig. 2 is only a partial drawing for reasons of space. However, the details can be seen in FIG. 3.

At one end of the trough (1) or the pouring channel Fig. 1, 2 there are Number of metal outlet openings (9) Fig.1.3 provided, through which the liquid metal exits and immediately in the mold or the mold or the like. flows in.

The lower part and also the upper part 1 + 11) Fig.5,7 and that Container (6) Fig, 3 are heated to the liquid metal to keep at the desired temperature.

Fig. 3 clearly shows the container (6), which does not need to be covered due to time constraints.
It is only important that inlet connections 4a are also provided on the bottom (10) of FIG. 3 of the container (6) FIG.

The slide (7) Fig. 1.3 closes the container (6) 3 compared to the trough (1) from the tilting melting furnace, from a robot or whatever construction always, a predetermined amount of liquid metal in the Container (6) Fig.3 can be filled.

After lifting the movable slide (7) Fig. 3, the liquid metal flows in the heated pouring channel or the pouring channel first up to the brake part web (13).
The lower part of the metal liquid continues to flow to the metal outlet openings (9) Fig. 1, 2 and then flows directly into the pouring openings of the mold or the like.

The arrangement of the metal outlet openings (9) Fig.1,2 can also be provided elsewhere.

In Fig. (4), (5) the upper part (11) is shown on which the Openings (12) for the extraction of the residual gas mixture can be seen are.

On the upper inner part side of the upper part (11), Fig. 5, 7, a brake part web (13), Fig. 5, is attached at a predetermined location, which only partially dips into the lower part (1), Fig. 1 or the pouring channel.
Due to the blown-in gas mixture, a residual substance of the blown-in gas mixture builds up on the surface of the pouring metal on the vertical side surface (14) Fig. 4.6 of the brake part web (13) Fig. 4.6 as real scabies (15) Fig. 4.6 .

In closer distance to the brake part web (13) Fig. 4,6 is in the upper part (11) Fig. 4,6 a detachable Intermediate piece (16) Fig. 4,6 attached, which is completely detachable or is also foldable.

The residual substance of the gas mixture or aluminum oxide formed is called real scabies at certain intervals scraped or removed.

6 and 7 show the complete pouring channel or the pouring channel.
The lower part (1) is covered with the upper part (11).
The injected gas mixture inevitably creates a certain overpressure inside the covered gutter, so that atmospheric outside air cannot penetrate at all.
The upper part (11) can rest freely on the lower part or be connected by hinges.

Detailed designs are quite possible, without thereby avoiding the idea of the invention.
For example, the trough and container can be made in one piece.
The trough should also always contain a certain amount of liquid metal and the like to prevent direct discharge into the mold. be secured.

Reference symbol overview

1

Lower part, pouring channel or pouring channel

2nd

Cover strip, cover frame

3rd

Bottom of the gutter or pouring channel

4th

Inlet connection

4a

Inlet connection

5

Through holes

5a

Through holes

6

enlarged container

7

movable slide

7a

End wall

8th

Sides of the gutter or the pouring channel

9

Metal outlet openings

10th

Bottom of the container

11

Top

12th

openings

13

Brake part web

14

vertical side surface

15

Spacer

16

detachable intermediate piece

Claims (9)

Disassembly, accumulation and removal of remaining residual substances4 of aluminum oxide in the case of liquid aluminum alloys in pouring channels, pouring channels or the like. before entering molds or mold units, where aluminum oxides are formed when atmospheric air acts on liquid aluminum alloys,
characterized, that flowing aluminum alloys in gutters, channels or the like. are not directly exposed to atmospheric air, Gutter channels, pouring channels or the like are covered, a gas mixture of nitrogen, chlorine and possibly fluorine gas is continuously blown through the lower flow surface of the flowing aluminum alloy, and a residual substance emerges on the surface of the flowing aluminum alloy. Decomposition, accumulation and elimination of residual substances according to claim 1,
characterized, that the pouring channel (1), the pouring channel as the lower part, is covered by the upper part (11), the liquid metal is only introduced into the lower part (1) and only flows to the destination, the upper part (11) is provided in the upper part with openings (12) through which the residual gas mixture is sucked off, the upper part rests on the lower part or is connected with hinges, the upper part (11) has an intermediate piece (16) which can be removed or opened by itself. Disassembly, accumulation and removal of residual substances according to claim 1 and 2,
characterized, that the lower part (1), the upper part (11) or the like. are made of metal, in particular as castings made of gray cast iron and are advantageously heated by means of gas or oil, but by means of electricity. Disassembly, accumulation and elimination of remaining substances according to claims 1 and 3,
characterized, that the cast iron parts contain 2 to 10% chromium as alloy components. Disassembly, accumulation and elimination of residual substances according to claims 1 to 4,
characterized, that the gas mixture is blown through inlet nozzles (4), which are arranged in a straight line or offset on the lower part (1), flows through the liquid flowing metal, exits as a residual component on the metal surface, is suctioned off and fed to a neutralization. Disassembly, accumulation and removal of residual substances, according to claims 1 to 5,
characterized, that a brake part web (13) is attached to the upper part (11), leaving a gap in the lower part (1), and only a part of liquid metal undisturbed underneath the brake part web - clean metal - continues to flow to the metal outlet openings (9). Disassembly, accumulation and elimination of remaining substances according to claims 1 and 3,
characterized, that the pouring channel (1) or the pouring channel is each provided with an insulating layer. Disassembly, accumulation and removal of residual substances according to claim 1, that dross builds up in the upper part of the flowing metal stream on the walls of the braking part web (13), in order then to be scraped off from there. Device for disassembling, accumulating and removing remaining substances according to claim 1 and further claims,
characterized, that at one end of the gutter (1), the pouring channel or the like. an enlarged container (6) is attached, into which a desired amount of liquid metal is introduced, and a gas mixture is blown in from below through through holes (5a).

Images