EP1344589B1 - Process and device for treating an alloy melt before a casting operation - Google Patents

Abstract

Production of a melt of an alloy for casting comprises: (a) placing the melt having a temperature lying above the liquidus temperature of the alloy in a crystallization vessel (14) heated to a temperature lying below the liquidus temperature; (b) adding an alloy as a powder; and (c) mixing the melt and powder using electrical and/or magnetic forces. An Independent claim is also included for a device for carrying out the process. Preferred Features: The melt is introduced into the crystallization vessel as a beam extending between two electrodes (17, 23) to which an electrical voltage is applied. A magnetic field is formed in the crystallization vessel. The melt is suctioned into the vessel under pressure and with the introduction of a protective gas.

Description

The invention relates to a method and an apparatus for processing a melt of an alloy for a casting process which is brought into a partially solidified state and contains crystallization seeds distributed over its volume.

The production of semi-solid alloys, for example, from a post from J.-P. Gabathuler and J. Erling "Thixocasting: a modern method for the production of molded components" known in the conference proceedings "Aluminum as a lightweight construction material in transport and traffic", ETH Zurich, pp 63 to 77 from 27.05.1994 known.

The object of the invention is to prepare a melt of an alloy in such a way that the distribution of the crystallization nuclei over the volume of the melt is as fine and homogeneous as possible before it is introduced into a casting mold.

This object is achieved by bringing the melt, which has a temperature above the melting temperature of the alloy, into a crystallization vessel heated to a temperature below the melting temperature, adding this melt in the crystallization vessel alloy as powder, and by means of electrical and / or magnetic forces melt and powder in the crystallization vessel are mixed together.

In particular, the pulverulent particles of the alloy, which are immediately enveloped by the melt, form crystallization nuclei, which by means of the electrical and / or magnetic forces are distributed homogeneously within the melt.

In an advantageous embodiment of the invention it is provided that the melt is introduced as a jet into the crystallization vessel, which extends between two electrodes, to which an electrical voltage is applied. Due to the so-called pinch effect of the jet is narrowed and compressed, which is already partially split during inflow into individual, liquid droplets. The crystallization vessel is thus not filled with a compact jet, but with a dispersed jet. Thus, the surface of the melt volume increases significantly, with a degassing takes place.

When the melt has completely flowed into the crystallization tank, the melt jet disappears, so that then the current flow is interrupted. In order to further achieve a dispersion and also to generate an electric field, it is then provided in a further embodiment of the invention that after introduction of the melt between the melt and an electrode, an arc is ignited.

In order to further promote the mixing of the melt contained in the crystallization vessel and to thereby finely distribute the crystallization nuclei, a magnetic field is formed in the crystallization vessel. The magnetic field and the electric field act differently on the melt and the particles therein, so that the mixing effect is promoted.

In a further embodiment of the invention it is provided that the melt is sucked into the set under reduced pressure crystallization vessel. By creating a vacuum in the crystallization vessel is further achieved that the inflowing jet of melt further dispersed and dissolves into individual drops. This also promotes the formation of nuclei.

In a further embodiment of the invention it is provided that the melt is supplied to the crystallization vessel with the supply of inert gas. In particular, when the shielding gas is supplied under pressure, the process is further improved. In addition, the shielding gas prevents chemical reactions of the alloy with the atmosphere, which could adversely affect the subsequent casting process.
In an apparatus for carrying out the method, there is provided a crystallization vessel having a melt inlet and a powdered alloy inlet having a heater and provided with electrodes applied to a voltage source in the region of its bottom and inlet.

Fig. 1

zeigt eine erfindungsgemäße Vorrichtung im Schnitt in schematischer Darstellung, die direkt an einen Ofen angeschlossen ist,

Fig. 2

eine abgewandelte Ausführungsform einer erfindungsgemäßen Vorrichtung,

Fig. 3

eine erfindungsgemäße Vorrichtung mit einer Zusatzeinrichtung zur Übernahme der aufbereiteten Schmelze und

Fig. 4

ein Nomogramm zur Voraussage des thermokinetischen Ablaufs.

Further features and advantages of the invention will become apparent from the following description of the embodiments illustrated in the drawings.

Fig. 1

shows a schematic section of a device according to the invention, which is connected directly to a furnace,

Fig. 2

a modified embodiment of a device according to the invention,

Fig. 3

a device according to the invention with an additional device for taking over the processed melt and

Fig. 4

a nomogram for the prediction of the thermokinetic sequence.

In a furnace 10, a melt 11 of a metal alloy, for example AlSi 9, is maintained at a temperature which is above the melting temperature of this alloy. The oven 10 is closed in a vacuum-tight manner and kept under vacuum by means of a suction device 12.

The furnace 10 is connected via a pouring line 13 with a crystallization vessel 14. The crystallization vessel 14 consists of a cylinder 15 of electrically non-conductive material, which has a thermal conductivity between 0.20 and 1.5W / mk. The cylinder 15 is closed at the top with a lid 16, which also consists of electrically non-conductive material. To the lid, the line 13 connects. For this purpose, the lid is connected to an inlet piece 17 made of electrically conductive material. The inlet piece 17 has a conically widening inlet opening. The lid 16 is followed by a suction line 18, which is connected to an exhaust 19. The lid 16 is further provided with a filler neck 20 through which alloy powder can be introduced into the crystallization vessel 14.

As the bottom of the crystallization vessel 14 is a piston 21, which also consists of an electrically non-conductive material. The piston 21 is guided in a subsequent to the crystallization vessel 14 cylinder 22, which is provided with a discharge opening, not shown. The cylinder 15 of the crystallization tank 14 is provided with an electrode 23 in the region of its bottom. As already mentioned, the inlet piece 17 is made of electrically conductive material. Between the electrode 23 and the inlet piece 17, a voltage source 24 is arranged, the voltage and above all the current strength of which is adjustable by means of an adjusting device 25.

The crystallization vessel 14 is associated with a preferably electric heater 26, which is preferably adjustable and which heats the crystallization vessel 14 at a preselectable temperature and holds at this temperature. Furthermore, the crystallization container 14 is associated with a magnetic coil 27, with which in the interior of the cylinder 15 of the crystallization vessel 14, a magnetic field is buildable.

The pouring channel 13 is equipped with a gate valve 28, via which the connection between the furnace 19 and the crystallization vessel 14 can be released and shut off. To the pouring channel 13, a supply line 29 connects, via which protective gas can be supplied with excess pressure, for example argon.

For the preparation of a melt, melt 11 is first introduced into the furnace 10. The furnace 10 is brought by means of the suction 12 to a vacuum of 0.5 mbar to 3 mbar. The crystallization vessel 14 is heated by means of the heater 26 to a temperature which is 3% to 50% lower than the melting temperature of the alloy in question. In the crystallization tank 14, a vacuum is generated by the suction 19, which is stronger than the vacuum in the furnace 10th

As soon as the slide 28 is opened, melt 11 is sucked into the crystallization tank 14. In this case, protective gas is supplied via the line 29. Due to the suction effect, alloy in powder form is also sucked in via the inlet connection 20. The powder is enclosed in the melt and distributed.

A voltage is applied to the electrode 23 and the inlet piece 17 so that a current whose size is less than 10 A flows in the jet of the melt. To a homogeneously dispersed mixture To obtain a magnetic field is generated by means of the magnetic coil 27 in the interior of the crystallization vessel 14, which leads to a radial movement of the melt.

After the entire melt has flowed into the crystallization tank, the circuit is first interrupted. Now the voltage is increased to values of 150V to 400V, so that an arc is ignited, in which a current with a strength up to 1300A can flow. In order to avoid directional crystallization, the electromagnetic field generated by the magnetic coil 27 is varied and continuously increased, for example, in the direction of filling.

After the melt has been processed in this way, the piston 21 is lowered, so that the melt flows out through the cylinder and its discharge opening and is processed further in a suitable manner. All known casting methods can be used.

In a modified embodiment, it is provided that the electrode 23 is integrated in the piston 21, which forms the bottom of the crystallization vessel 14.

According to the embodiment Fig. 2 the voltage source 24 is connected to two electrodes 30 and 31 of the cylinder 15 of the crystallization vessel 14. The second connection is made to the pouring channel 13. In this embodiment, the piston 21 moves during the filling of the melt continuously down, then successively the electrodes 30 and 31 are used, which with the piston movement via switches 32 and 33 and be switched off.

According to the embodiment Fig. 3 For example, the melt prepared in the crystallization vessel 14 is transferred to a storage or transport container 34 in which it is in the processed state is held. This container 34 is provided with a suction 35, so that a negative pressure can be applied to it. It is provided with a heater 36 and a solenoid 37. Likewise, it is equipped with an electrode 38. The two end walls of the container 34 are formed by pistons 39 and 40. The container 34 can also be used for shaping.

With the in Fig. 4 shown nomogram can predict the thermokinetic sequence. The nomogram shown applies to the alloy AlSi9Cu ₃ . The amount of powdered alloy added with a grain size of about 125 microns to about 400 microns is applied in proportions by weight. The temperature difference ΔT in [C °] is the difference between the casting temperature and the melting temperature of the alloy. If an amount of powdery alloy is added, which is in the nomogram region A, this causes only a reduction of the temperature of the melt. The melt is thus placed in a semi-solid state without the powdery particles forming nuclei. However, when an amount of powdered alloy is added to reach the nomogram region B, the powdery particles function as additional, unmelted nuclei. If the addition of powdered particles in the nomogram region C, the two processes will run side by side, ie a reduction of the superheat temperature and nucleation due to unmelted particles.

Of course, different nomograms must be made for different alloys.

Claims (9)

1. A method for preparing a metal-alloy product for a casting process wherein the product is brought to a semi-solidified state and in which crystallisation nuclei are distributed throughout the volume, characterised in that the melt has a temperature greater than the melting temperature of the alloy the alloy is introduced into the crystallisation vessel which is below the melting temperature and that the melt introduced is an alloy in a pulverised form, the melt and the alloy are mixed in the crystallisation vessel by applying electrical and magnetic forces thereto.
2. The method according to claim 1, characterised in that the melt is introduced into the crystallisation vessel in the form of a stream which flows between two electrodes which are supplied with electrical power.
3. The method according to claim 1 or 2, characterised in that after the introduction of the melt, an electrical arc is established between the melt and the electrode.
4. The method according to one of claims 1 to 3, characterised in that a magnetic field is established within the crystallisation vessel.
5. The method according to one of claims 1 to 4, characterised in that the melt is aspirated into the crystallisation vessel which is placed under a vacuum.
6. The method according to one of claims 1 to 5, characterised in that the melt is introduced into the crystallisation vessel with the supplying of a protective gas.
7. An apparatus for implementing the method according to one of claims 1 to 6 characterised in that a crystallisation vessel having an inlet for the melt and an inlet for an alloy in pulverised form and a heating arrangement which is provided with measures to produce a magnetic field effective in the interior and with electrodes connected to an electrical supply in the base area and inlet.
8. The apparatus according to claim 7, characterised in that the crystallisation vessel is connected to a means for creating a vacuum therein.
9. The apparatus according to claims 7 to 8 characterised in that the crystallisation vessel is connected to the furnace via a conduit which is provided with an inlet for protective gas.

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