EP1442810B1 - Method for manufacturing castings made of an alloy by injection moulding - Google Patents

Description

The invention relates to a method for the production of castings from a Alloy by injection molding according to the preamble of Claim 1.

Such a method is already known (DE 199 07 118 C1). This will be a particulate metallic Material, eg. B. a magnesium alloy containing the Main component forms and dendritic properties has, the material supply opening at the upstream Supplied to the end of the screw of a Thixospritzgießmaschine, while the other metallic material, eg. As zinc or an AlZn alloy is fed downstream. By doing The screw extruder will use the magnesium alloy over it Solidus temperature heated so that they are in the storage zone in a thixotropic state is present. If a low melting metal such as zinc, the screw extruder the storage zone is fed, it melts, without having to the still solid magnesium alloy to mix homogeneously can. In addition, hardly manageable sealing problems at the point of zinc injection on.

The production of large quantities of castings Alloys are generally made by die casting. The Alloy is used in the form of Giessmasseln, by conventional melt metallurgy from the Alloy components are obtained.

For die casting, the desired alloy must therefore be melted twice, once to Production of Gießmasseln and the other in the Pressure casting plant. For a number of alloying elements In addition, problems arise through the compliance of the nominal alloy composition difficult or even is excluded. So is by the burning problem the Applicability of alloying elements limited, the one have high oxygen affinity, z. As Ca, Si, Hf, Y or Cerium. The same applies to alloying elements, which by their high vapor pressure tend to evaporate, z. Zn. Other alloying elements are limited or not at all Soluble in the base metal, allowing it to float or to Soil sink. So z. As zirconium, titanium and silicon in Magnesium barely soluble and iron, chromium, molybdenum, Vanadium, beryllium and boron insoluble. Other Alloy elements, also soluble, with a high Atomic weight, especially those with one order many times higher atomic weight than that of the base metal, tend to gravitational seeding, z. B. Zn. Another Limitation is the characteristic of some die casting Alloying elements, e.g. B. of calcium, which Increase warm crack tendency.

The object of the invention is an easy to perform Process for the preparation of Castings from different alloys for To make available.

This is inventively by the in claim 1 marked procedures reached. In the Subclaims are advantageous embodiments of inventive method played.

For the process according to the invention, a commercially available Thixos injection molding machine used in the Screw conveys the material mixture to a storage zone, in the formed alloy with the screw, to it is formed axially displaceable back and forth, through the Nozzle ejected into the injection mold with the mold cavity becomes. The housing of the Thixospritzgießmaschine is through a heater, such as heaters, on the required temperature heats to the metallic At least partially melt materials.

The at least two particulate metallic ones Materials can be two different alloys or an alloy and a non-alloyed (pure) metal or two unalloyed (pure) metals. Among metals are also to understand semi-metals, such as boron or silicon.

The partially molten state that the alloy passes through Heating and shearing with the screw in the storage zone can be achieved that the as metallic material used alloy on a Temperature between the solidus and the liquidus temperature is heated, or if z. B. two unalloyed mutually insoluble metals with different melting points Only use the metal with the lower one Melting point is melted. According to the invention the at least two metallic materials also completely be melted, d. H. as a metallic material The alloy used can also be above the liquidus temperature heated, or when pure as a metallic material Unalloyed metals can be used, the metals also be completely melted.

The particulate materials, called granules or Powders are used according to the invention as Mixture of the material supply opening in the housing of the Screw extruder at the upstream end of the screw fed.

Because z. B. by a different particle size and / or a different density of metallic materials a segregation in the reservoir can occur separate reservoir for the metallic materials used, from which the metallic materials of the Material supply opening in the housing of the extruder separated so be dosed that they only at the Mix the material supply port.

That is, it is only one feed opening in the housing of the Screw extruder present over which the metallic Materials are fed to the extruder.

Because separate feed openings have the disadvantage that the Materials added in time to the screw be, so the one material the trough-shaped Worm gear occupied before the second material is metered becomes.

By the inventive simultaneous metered addition of Materials at a single feed opening will be the Mixture so to speak generated in situ, so no Disconnecting phenomena can occur, as well as little temporal offset with the resulting Mixing problems. In this way, after the inventive method exactly reproducible Make alloys.

The at least two metallic particulate Materials preferably have a similar shape and Size distribution on. So should the middle one Particle diameter of one material from that of the other not more than 1: 5 to 5: 1 to deviate submissions.

The temperature of the screw extruder at the Fluid supply opening, d. H. the housing and the screw in this area, will feed at least two Alloys below the solidus temperature of the alloys, with supply of at least one alloy and at least a metal below the solidus temperature of the alloy and below the melting temperature of the metal and with supply of at least two metals below the melting temperature of the Held metals. Thus, the solid mixture is homogeneous in Extruder distributed melted.

The temperature of the screw extruder can be determined by the Increase the fluid supply opening towards the nozzle. she can however, in front of the storage zone also higher than in the Be storage zone. Thus, the storage zone becomes preferable kept at a temperature that is optimal Spray temperature corresponds to, but also lower than the temperature for melting can be.

In general, a metallic material provides the Main component and the at least other metallic Material is the minor component. The main component can Be magnesium or a magnesium alloy, for. Eg AZ91, AM60 or AS41.

The first material that made up the main component is, can via a metering device, preferably a Dosing screw, the material supply opening of a Feeding hopper or the like reservoir supplied become. The reservoir can this material be supplied for example with a suction conveyor. The delivery characteristic of the dosing screw, d. H. of the Mass flow of this material as a function of the Screw speed must be used to determine the metered Quantity to be determined.

In the second material, so the minor component can z. B. act to a pure element. The second material may also be from a hopper or the like Reservoir via a metering device, preferably a screw feeder or a chamber feeder, the Material supply to be supplied. The delivery characteristic This second metering device must also be determined become.

By an inert gas, which fed to the material supply port becomes, the admission of air into the screw extruder becomes prevented. This can be done at the material supply opening Approach be provided, with an inert gas is provided to fill the approach with inert gas. When Inert gas is preferably used argon, as it is a higher density than air and thus the air from the Approach displaced.

The approach can do this, except for the inert gas and the Outlet openings of the metering devices closed be educated.

With the method according to the invention can also Alloy elements are alloyed, the conventional melt metallurgical process to burn-off problems due to the high melting temperature and / or the high Oxygen affinity, for example calcium, Silicon, hafnium, yttrium and cerium. The oxygen affinity of the alloyed metallic material may be larger than that of magnesium. The oxygen affinity of a metal generally corresponds to its normal potential in the Voltage range. According to the invention can readily Alloy elements alloyed with a normal potential in particular, which is more negative than -2 volts Alloy elements with a normal potential, the more negative than that of magnesium (-2.37V), for example Calcium, hafnium, yttrium or cerium. Likewise Alloy elements with a high melting point of more be alloyed as 1000 ° C, for example silicon.

Furthermore, according to the invention, alloying elements can be alloyed which, due to their high vapor pressure, tend to to evaporate, z. For example, sodium, potassium, zinc. For example, zinc has B. a vapor pressure of about 100 mbar at 620 ° C and about 1000 mbar at 900 ° C. According to the invention can thus readily Alloy elements with a vapor pressure of more than 10 mbar at 600 ° C or more than 100 mbar at 900 ° C be used. So can the alloyed metallic Material at a temperature at which the Main component in the liquid or liquid state is located, have a higher vapor pressure than magnesium. It is also possible according to alloying elements use that only limited or not at all in the Base metal are soluble, so they float or too Soil sink. So can magnesium as a base metal z. B. Zirconium, titanium and silicon are alloyed up to a customary in the melt metallurgy temperature of 1000 ° C a solubility of significantly less than 10 wt.% in molten magnesium, furthermore iron, chromium, Molybdenum, vanadium, beryllium and boron, which are in magnesium insoluble.

Furthermore, according to the invention alloying elements, too soluble, with a high atomic weight, especially those with a much higher atomic weight than that Base metal can be used without a Gravity segregation occurs. Depending on the number of through metallographic examination detectable phases or Structural constituents can according to the invention be single-phase (homogeneous) or multi-phase alloys arise.

Since according to the invention, the alloy with a lower Temperature can be supplied to the tool than when Die casting, the hot crack tendency and the tendency of the Alloy to stick, in particular by certain Alloy elements, such. As calcium is caused, reduced.

If magnesium or a magnesium alloy than Main component can be used with it According to the invention magnesium-based alloys without the in the melting metallurgy existing limitations following alloying elements as minor components be prepared: alkali and alkaline earth metals, z. B. Sodium, potassium, lithium, strontium, beryllium and calcium, Group 2B elements of the periodic table, such as zinc, the Group 3, such as boron, Group 3A, such as yttrium or the Lantanides such as cerium, group 4, such as silicon, the group 4A, such as titanium, zirconium or hafnium, group 5A, such as Vanadium, group 6A, such as chromium or molybdenum, as well as Ferrous metals, especially iron.

In the method according to the invention forms in general the one metallic material is the main component while the at least one other metallic material the Forms minor component. The weight percentage of Main component is at least 50%, preferably 80% and more of the produced alloy.

The maximum temperature of the screw extruder is so set that they are used in an alloy as Main component above the solidus temperature, especially between the solidus and the Liquidus temperature of the alloy is and in a pure Metal as the main component above the melting point of Metal.

Preferably, the main component has a Solidus temperature or a melting point, the below the solidus temperature or the melting point of at least one minor component lies.

When the minor component is soluble in the main component is, according to the invention, the screw extruder on a Temperature above the solidus temperature or the Melting temperature of the main component is heated and thus the Secondary component dissolved in the main component. Due to the strong mixing in the screw extruder can According to the invention also with a refractory Minor component at a relatively low level Operating temperature of the screw extruder a homogeneous, single-phase melt can be obtained.

So z. B. at a temperature of the screw extruder from 600 to 620 ° C with a magnesium alloy as Main component and calcium as a minor component after the inventive method with a magnesium alloy Calcium, although the melting point of Calcium is 840 ° C. This is also a very high Content of calcium in a magnesium alloy of z. B. 10 wt.% Or more can be produced.

The following examples serve for further explanation the invention.

example 1

The material feed opening of a screw extruder with a dosing screw each 95 parts by weight of a Magnesium alloy AM60, as TIX06 quality granules and 5 parts by weight of zinc as spherical granules with a particle size of <2 mm added. The temperature the housing of the extruder was förderabwärtig of the Feed opening set to a maximum of 620 °. there has been a obtained homogeneous single-phase melt, d. H. that had zinc in the liquid phase of the predominantly molten Magnesium alloy dissolved homogeneously.

Example 2

Example 1 was repeated except that 90 Parts by weight of the magnesium alloy and 10 parts by weight Zinc were used. It also became a homogeneous one obtained single-phase alloy.

Example 3

Example 1 was repeated except that 97 Parts by weight of the magnesium alloy and 3 parts by weight Calcium were used. It became a homogeneous single-phase Alloy obtained by high creep resistance distinguished.

Below is an embodiment of an apparatus for carrying out the method according to the invention closer by way of example with reference to the drawing explained, the only figure schematically a partial cut view of a worm extruder to Thixos injection shows.

The screw extruder then has in a housing 1 a Screw 2, which by a drive unit. 3 is driven. Further, an accumulator 4 provided by the screw 2 with a not Pistons are shown axially pushed back and forth can. In the drawing, the screw 2 is in position after the ejection of the alloy from the storage zone shown. When the snail is withdrawn, arises between her and the nozzle 5 the storage zone in which collect the alloy that flows through the nozzle 5 in the Mold cavity 6 of the tool 7 is ejected to the To form casting, not shown.

The housing 1 has at the upstream end of the Check 2 a material feed opening 8, which with a nozzle-shaped projection 9 is provided, which at its from the feed opening 8 facing away from the end is closed.

At the approach 9 are two dosing screws 10, 11, connected. With a dosing screw 10 is of a feed hopper 12, the metallic material A of Material supply 8 dosed. With a Suction conveyor 13, it is the hopper 12th fed. With the other metering screw 11 is the metallic material B from a feed hopper 14 of the Material supply 8 dosed.

Below the two inlet openings 15, 16 of the Metering screws 10, 11, the approach 9 a Inertgaszuführung 17 on. With heating bands 18, the away from the material feed opening 8 on the Housing 1 and the nozzle 5 are arranged, the extruder heated.

Claims (10)

1. A method for producing castings from an alloy by injection molding wherein at least two particulate metallic materials of different composition, which consist of at least two alloys or at least one alloy and at least one pure metal or at least two pure metals, are supplied to a screw extruder with a housing (1) provided with heating means (18) and with a material supply opening (8) at the upstream conveying end of the screw (2), at least partly melted in the screw extruder and ejected from a storage zone via a nozzle (5), characterized in that the particulate metallic materials of different composition are charged separately from separate storage vessels (12, 14) to the one material supply opening (8) in the housing (1) of the extruder such that they mix only at the material supply opening (8), and the temperature of the screw extruder at the material supply opening (8) is held below the melting point of the at least one metal or at least two metals or below the solidus temperature of the at least one alloy or at least two alloys.
2. A method according to claim 1, characterized in that a metallic material forms the primary component, and at least one other metallic material the secondary component.
3. A method according to claim 2, characterized in that the secondary component has no solubility in the primary component in the liquid state up to 1000°C.
4. A method according to claim 2, characterized in that the secondary component has a solubility of at most 10 wt % in the primary component in the liquid state up to 1000°C.
5. A method according to claim 2 or 3, characterized in that the primary component is magnesium or a magnesium alloy
6. A method according to any of the above claims, characterized in that at least one metallic material has a higher oxygen affinity than magnesium.
7. A method according to any of the above claims, characterized in that at least one metallic material has a higher vapor pressure than magnesium at a temperature at which the primary component is in the semiliquid or liquid state.
8. A method according to any of the above claims, characterized in that at least one of the metallic materials is or contains a metal whose atomic weight is at least twice as great as that of the primary component of the alloy.
9. A method according to any of the above claims, characterized in that an inert gas (17) is supplied at the material supply opening.
10. A method according to claim 7, characterized in that the inert gas used is argon.

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