DE2001341A1 - Alloy or mixed metal based on molybdenum - Google Patents

Description

Tungsten and tungsten-based alloys are currently used as the material for the injection molding nozzles for injection molding of high-melting materials such as copper, brass and bronze because of the particularly good material properties of these metals in relation to other known materials for producing such tools.

Tungsten and tungsten alloys have particularly good properties for this purpose; on the other hand, it is disadvantageous that tungsten - based on weight - is a very expensive material. The specific weight of the tungsten of 19.3 g / cm [high] 3 is one of the highest occurring specific weights. As a result, the volume occupied by the unit weight of tungsten is smaller than that of most other metals. As a result, you need - in terms of weight - more material to make a given shape or other tool than if you were to make that shape or tool from most other metals.

Molybdenum only has a specific weight of 10.2 g / cm [high] 3, i.e. H. about 52.8% the density of tungsten. This means that - in relation to tungsten - almost twice the volume can be filled with the same mass of molybdenum. Since molybdenum is normally considerably cheaper than tungsten, there is another economic advantage of molybdenum compared to the use of tungsten. In addition, molybdenum is a refractory metal with a particularly high melting point. These two properties make it appear suitable as a material for the manufacture of injection molding nozzles, nozzle cores and other tools for casting.

It is known that forged molybdenum and especially molybdenum with less than 1% admixture of elements such as titanium and zirconium is particularly suitable for the production of injection molding nozzles, injection molding cores and other correspondingly stressed parts of injection molding machines when alloys are processed at high temperatures should be what z. B. is the case with yellow brass.

When producing such molybdenum alloys, a blank is generally formed from a vacuum melt. The blank is then hot forged or otherwise formed into a block of such dimensions that an injection molding nozzle, an injection molding core or another part of an injection mold can be produced from it by machining.

It should be noted, however, that forging and / or other processing steps in the finished nozzle or injection mold can result in a preferred grain orientation. As a result, the ductility of the nozzle or the molded part is perpendicular to the

The structure of the elongated grain is impaired in a technically undesirable manner. This previously unavoidable irregularity results in the above-mentioned molybdenum alloys cracking or breaking along these planes.

The melting, casting and subsequent hot forging and further processing naturally also increases the production costs of the finished tool considerably. As a result, the above-explained fundamental economic advantages of the lower specific weight, the resulting larger specific volume and the lower costs of molybdenum can often not only not be used, but in most cases increased costs must be accepted.

The invention is directed to the creation of molybdenum alloys and / or compositions, in particular for the production of nozzles, cores, core rods and other molded parts for treating metals at high temperatures, such as. B. in the injection molding of copper, bronze, brass, steel and other metals or alloys.

In particular, the invention seeks to exploit the economic advantages of molybdenum, which result from its relatively low specific weight, the large specific volume and the relatively low price of molybdenum, namely to create tools of the type mentioned that have a long service life and can be manufactured at a reasonable price.

The invention is further directed towards using the methods of powder metallurgy for the production of molybdenum alloys and / or compositions which have those properties have, which are necessary for the production of nozzles, cores, injection molded parts and the like.

The invention makes inter alia. make use of sintering in the liquid phase in the manufacture of molybdenum alloys or compositions, this liquid phase being obtained from metal powders.

Furthermore, the invention aims to find alloys and metal compositions consisting essentially of molybdenum in which no preferred grain orientation is established, so that corresponding tools or objects have essentially the same mechanical properties in all directions.

The invention is explained in detail below:

The alloys or compositions according to the invention are composed of at least three metallic elements, molybdenum being the main component. To use an alloy or composition according to the invention as a material for casting molds, casting cores or other parts of injection molding nozzles or molds for forming particularly hot molten metals, the molybdenum content of the alloy or mixture should be at least about 80% by weight.

The other two or more elements form an alloy which, when molten, dissolves a significant amount of the molybdenum, causing a phenomenon called sintering in the liquid phase to occur. In the following, in a table (see page 6), the percentages by weight of the compositions of the alloys are given which are to be sintered in the liquid phase of the alloy or the composition to lead. The total weight of the elements forming the alloy is up to 20% of the mass consisting of molybdenum and alloy.

The table gives inter alia as a composition. a "remainder" in each case. It is expressly pointed out that - in order not to overload the table - the so-called "rest" is only the essential part of the rest, so that the alloy can consist of more than two metals in the manner described above.

In the table shown, the components of the alloy - without the molybdenum, which is the main component - are also shown in percentages by weight based only on the alloy. The composition given in the first line of the table can therefore be e.g. B. have the following components:

80% Mo + 20% alloy (alloy: 2% B + 98% Co) or: 80% Mo + 20% alloy (alloy: 8% B + 92% Co) or: 90% Mo + 10% alloy (alloy: 2% B + 98% Co) or: 90% Mo + 10% alloy (alloy: 8% B + 92% Co) etc.

The possible compositions given further in the table can of course vary in the same way within the given limits.

As already explained above with reference to the term "remainder", further alloying elements can also be added to the alloys produced according to the invention, in accordance with the respective intended use of the material. So z. B. certain hardness elements are added, which are known to the person skilled in the art.

The designs of the desired workpieces can be made from powders according to the above alloys, for. B. can be produced as follows:

A composition according to the table can be pressed into a desired shape, then finely machined and then sintered in order to obtain a correspondingly composed alloy. Further machining and / or a grinding process can then take place if this is necessary or expedient.

In another embodiment, the composition can also be first pressed and then sintered, in which case machining and / or grinding is carried out at the end of the manufacturing process. Obviously, you can work with very tight tolerances in the two processes described; So there is little waste.

The metal powders for pressing can already be powdered alloys according to the table given above or the powder can consist of various powder components, the components being the metals of the composition according to the table. Of course, it is also possible to combine the two options mentioned above so that the metal powders used consist of both alloys and pure metals.

Any of the known binders can be used in pressing the powders, e.g. B. zinc stearate and / or paraffin. It is also possible, if desired, to use binding processes in which no special binding agent is necessary. For example, the binding particles to be compressed can be placed in a sack of plastic material and then a liquid pressure of at least about 700 kg / cm 2 can be applied to the particles through the sack to bind the particles together.

The sintering temperature for processing an alloy according to the invention is approximately 1000 to 1600 ° C. An additional pre-sintering with a temperature range of about 300 to 1000 ° C. is expediently used.

In both cases, i. H. in the case of pre-sintering and sintering, work must be carried out in an atmosphere which does not contain any oxygen. You can z. B. sinter in a vacuum or in a non-oxidizing gas, e.g. B. hydrogen, nitrogen, argon, helium, etc. It can also be sintered in an atmosphere of dissociated ammonia.

The alloys according to the invention are particularly suitable as a material for injection molding nozzles, cores and corresponding parts of the molds when casting copper and copper alloys, such as. B. brass and bronze, other refractory metals such as iron, nickel and cobalt alloys. Corresponding injection molds and nozzles are of course just as suitable for the injection molding of low-melting metals, e.g. B. for processing aluminum, aluminum alloys, magnesium and magnesium alloys etc.

The properties of the alloys or compositions according to the invention are generally in the range of the properties of commercially available, pure molybdenum, it being found that some of the new alloys or compositions have considerably greater mechanical strength both at room temperature and at elevated temperature .

Claims (20)

1. Molybdenum alloy with at least 80% by weight of molybdenum and at least two other additional metals, the additional metals forming an alloy which dissolves a considerable proportion of molybdenum in the molten state. 2. Alloy according to claim 1, characterized in that it consists essentially of molybdenum and the dissolving, alloy-forming metals. 3. Alloy according to claim 2, characterized in that at least one of the metals is boron. 4. Alloy according to claim 2, characterized in that at least one of the metals is manganese. 5. Alloy according to claim 2, characterized in that at least one of the metals is vanadium. 6. Alloy according to claim 2, characterized in that at least one of the metals is silicon. 7. Alloy according to claim 3, characterized in that the alloy additionally contains an element from the group Co, Fe, Ni, Nb, Ta, Cr, V and mixtures thereof. 8. Alloy according to claim 4, characterized in that the alloy also contains an element from the group consisting of Ni, Fe, Cu, Ti, Zr, U, Si, Co and mixtures thereof. 9. Alloy according to claim 5, characterized in that the alloy also contains an element from the group Fe, Ni, Co, Mn and mixtures thereof. 10. Alloy according to claim 6, characterized in that the alloy additionally contains an element from the group consisting of Ni, Fe, Co, Cu, V and mixtures thereof. 11. Use of the metal composition according to claim 1 as a material for a molding part of an extruder or an injection molding machine. 12. Use according to claim 11, characterized in that it is part of a casting mold. 13. Use according to claim 12, characterized in that the tool is one half of a casting mold. 14. Use according to claim 11, characterized in that the tool is a casting mold core. 15. A method for producing a composition according to one or more of the preceding claims, characterized through the following process steps: a) pressing of molybdenum powder and a powder which contains at least two other metals which in turn form an alloy in the molten state, this latter alloy dissolving molybdenum to a considerable extent and the pressing serves to form a solid body; b) heating the solid body obtained in this way and at such a temperature that sintering takes place in the liquid phase and a dense body made of a molybdenum alloy is created as a result; and c) making the sintered body into the desired shape without hot working or hot forging. 16. The method according to claim 15, characterized in that the local process step b) is carried out before the local process step c). 17. The method according to claim 15, characterized in that method step c) is carried out before method step b). 18. The method according to claim 15, characterized in that step c) is carried out at least partially by machining. 19. The method according to claim 15, characterized in that at least part of the additional Powder containing metals is a mixture of powders formed by the elements. 20. The method according to claim 15, characterized in that at least part of the powder containing the additional metals is a powdered alloy of the metals.