WO1987006623A1

WO1987006623A1 - Continuous production of alloys

Info

Publication number: WO1987006623A1
Application number: PCT/GB1987/000286
Authority: WO
Inventors: Brian Maddock
Original assignee: Alform Alloys Ltd
Current assignee: Alform Alloys Ltd
Priority date: 1986-05-01
Filing date: 1987-04-30
Publication date: 1987-11-05
Anticipated expiration: 1988-11-01
Also published as: ES2028135T3; EP0264418B1; DE3774995D1; JPS63503229A; EP0264418A1; GB8610717D0; ATE70088T1; EP0244255A1

Abstract

An apparatus and method for the continuous production of molten metal alloy. A furnace (1) is used to melt a basic metal of the alloy, and that is transferred to a valve (2). Controlled amounts of at least one alloying metal are fed into the supply of molten metal in valve (2) for combining with the basic metal of the alloy to form a controlled supply of the desired alloy.

Description

CONTINUOUS PRODUCTION OF ALLOYS.

* TECHN ICAL F I ELD f- The present invention relates to the continuous production

5 of alloys and in particular, though not exclusively, to the product ion of al uminium alloy continuously. BAOOOJND ART

Mol ten aluminium alloy is used in a variety of production methods, for example in continuous casting and to supply a "Conform"

10 extruder. Conventionally a furnace full of pure aluminium is mel ted, and the molten aluminium doped with the necessary quantities of alloying metals to produce a desired alloy formulation. As a method of producing a large quantity of molten aluminium alloy this method is reasonably satisfactory. However, it is quite com mon to

15 only want to produce a relatively small quantity of a finished product of a particular alloy, for example when using a Conform extruder. The practice in the past has been to produce a furnace full of the desired molten alloy and to use as m uch as is necessary for a production run and then to discard the rest, with only a

20 l imi ted possi bility of recycling. This known technique has resulted in a considerable waste of alloy, and consequently increased the expense of small scale production of products of a particular alloy, to the extent that it may not be worthwhile maki ng only small amounts of a product.

25 DISCLOSURE OF THE INVENTION

The present invention seeks to provide a method and apparatus for the production of molten alloy metals in controllable quant i t ies .

Accordi ng to a first aspect the invention provides an

30 apparatus for the continuous production of molten metal alloy,

* compr i s i ng: a furnace for melting a basic metal of the all oy, means ^ for receiving a controlled supply of molten metal from the furnace, and means for providing to the molten metal in the receiving means control l ed amounts of at least one alloying metal for combining with 35 the basic metal of the all oy to form a controlled supply of the des ired alloy.

Preferably the apparatus includes a feedback control system whi ch determines the rate of production of the alloy and adjusts the amount of alloying metal being supplied. In a preferred embodiment a valve controls the flow of the mol ten basic metal from the furnace and the val ve assembly forms part of the receiving means and the alloying metal is introduced into the basic metal flowing through the valve, and together they are supplied to an alloying chamber where the alloy is temporarily contained to allow the alloying elements to diffuse uniformly through the basic molten metal.

The alloying metal(s) can be held in a "master" alloy of the basic metal with high coneentration(s) of the alloying metal(s). According to another aspect of the invention there is provi ded a method of producing molten metal alloy comprising

(a) melting a basic metal,

(b) supplying a ^controlled flow of the molten basic metal, and

(c) introducing into the controlled supply of molten basic metal, at least one alloying metal in controlled amounts in order to produce, continuously, an alloy of controlled and desi red composition.

A preferred embodiment' of the invention will now be descr ibed by way of example and with reference to the accompanying drawings :

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 is a schematic section through an apparatus according to the preferred embodiment of the i nvent ion; and

Figure 2 is a combination of a part of the diagram of Figure 1 and a block schematic diagram of a control circuit for the apparatus of Figure 1. DESCRIPTION OF PREFERRED EMBODIMENTS

In the subsequent description the apparatus of the preferred em bodi ment will be described being used in conjunction wi th a "Conform " extruding apparatus. It is to be appreciated that the invention is not limited to the use of the apparatus in conjunct ion with any particular apparatus which uses, or method of us ing, the molten metal alloy produced by the apparatus of the invent ion. A typical alternative to "Conform " extrusion apparatus woul d be a cont inuous cast ing machine.

Figure 1 shows a preferred em bodiment of the invention, wherein a molten al uminium alloy is produced and supplied to a "Conform" extruding apparatus. A furnace 1 is connected through a mixing and flow control valve 2 to an alloying chamber 3, which val ve has an upper port 2a. A conveying apparatus 4 is arranged to supply a molten alloy from the alloying cham ber 3 into a Conform apparatus 5. A sluice gate 6 controls run-off from the alloying chamber 3 to a run-off 7.

In the preferred embodiment aluminium A is melted in the f urnace 1 and run into the mixing control valve 2. A " Master Alloy"

B in rod form is also -supplied into the mixing control valve 2 through port 2a, to be melted by the molten al uminium A. The molten al l oy mixture runs into the alloying cham ber 3 where the alloying metals in the " Master Alloy" diffuse throughout the basic al uminium metal to produce a consistent alloy of desired composition. The "Master Alloy" rod B is of known alloy composition and is cont i nuously fed into the mixing control val ve 2 to produce the des i red output alloy.

As can be better seen in Figure 2 the feeding of the "Master Alloy" B is controlled by a pair of rollers 10. The speed, of rotation of the rollers 10 is controlled by a control circuit 20. A sensor 8 detects the area of the extrusion output from the Conform extruder 5 to provide an area input A to control circuit 20 and a speed sensor 9 provi des an input V related to the speed of product ion of the extrusio n material. In addition the control ci rcuit 20 is supplied with input data giving the required alloy composi t ion and the composition of the master alloy B which is to be added to the basic molten alum inium A. From the data supplied the cont rol circuit 20 controls the feed rolls 10 to provide the master al loy rod at an appropriate rate to produce the desired output alloy..

At termination of extrusion with a particular alloy the valve 2 is closed shutting off flow of aluminium from the furnace 1 and the master alloy B is no longer supplied. The remaining, 5 relatively small quantity of alloy in the mixing control valve 2 and alloying chamber 3 is run-off through run-off 7 by opening the sluice gate 6. It will be appreciated that only a relatively small volume of alloy is run-off. Production of an alloy of differing composition can then begin, with the appropriate data being provided

10. to the control circuit 20.

In some circumstances it may be advantageous to agitate the alloy mixture in the alloying chamber 3 to ensure the consistence of the alloy. This may be done by means of a metal mechanical or an electromagnetic stirer.

15 Although the described embodiment makes use of a master alloy in rod form it would be possible to use pellets or granular master alloy for feeding to the basic aluminium metal. In such alternative eases it would be obviously necessary to replace the feed rolls 10 with some means for regulating the supply of master

20 alloy appropriate to the form of alloy material being used.

An example of production of one alloy will now be described for the purposes of illustration only.

The control circuit 20 is supplied with data such as:- (1) extrusion speed V, 5^' (2) extrusion cross section area A, which together with the extrusion speed V enables it to calculate the volume or weight per minute flowing through the valve,

(3) alloy composition required, and

(4) composition of alloying rod or pellets. 0 Typical alloying calculation: extrusion speed 30 metres per minute, cross section area 100 sq rim, weight per minute = 30 x 100 x 2.7 = 8.1 Kg/min,

1000 35 bath purity 99.8% aluminium, composition of alloying pellets say Al 50%, Si 25%, Nig 25% (master alloy), for 6063 Alloy (Al fife Si.6) weight/minute silicon required = 8.1 x .006 = .048 Kg/min 5 weight/minute Magnesium required = 8.1 x .006 = .048 Kg/min total weight of alloy elements = .096 Kg/min weight of master alloy required = .096 = .192 Kg/min .5 10. Hence wire or pellets would be added at the rate of 192 grams per minute to create 6063 from high purity aluminium, weight/metre 6rπ_ι master alloy = 65 gn.m master alloy rod speed = 192 = 2.95 m/minute

65

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I f, for the sake of example the extrusion speed were suddenly reduced to 10 metres per minute, the control system would reduce the master alloy rod speed to 0.98 m/min to maintain the correct alloy composi t ion.

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Claims

CIAI 5:

1. An apparatus for the continuous production of molten metal alloy, comprising: a furnace (1) for melting a basic metal of i the alloy, means (2) for receiving a controlled supply of molten metal from the furnace, and means (20, 10 ) for providing to the mol ten metal in the receiving means (2) controlled amounts of at least one alloying metal for combining with the basic metal of the al loy to form a controlled supply of the desired alloy. rα

2. An apparatus as claimed in claim 1, wherein there is a feedback control system (29 ) which determines the rate of product ion of the alloy and adjusts the amount of alloying metal being supplied by the alloying metal providing means (10 ).

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3. An apparatus as claimed in claim 1 or claim 2, wherein a valve (2 ) controls the flow of the molten basic metal from the furnace (1 ) and the valve assembly forms part of the receiving means (2) and the alloying metal is introduced into the basic metal

20 f lowing through the valve (2 ), and the valve (2 ) is connected to an al loying chamber (3) where the alloy is temporarily contained to al low the alloying elements to diffuse uniformly through the basic mol ten metal.

25 4. A method of producing molten metal alloy comprising

(a) melting a basic metal,

(b) supplying a controlled flow of the molten basic metal, and

(c) introducing into the ^' controlled supply of molten basic 0 metal, at least one alloying metal in controlled amounts in order to produce, continuously, an alloy of controlled and desired composi t ion.

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