EP2014394A1 - Method, where metal powder, which has been heated by microwaves, is extruded - Google Patents

Abstract

In a process to heat metal powder and extrude this as a profile, the powder is heated to a temperature below that of the melting point. The powder is extruded under pressure through a matrix aperture and converted to a profile. The metal or metal alloy powder is a reactive material whose outer surface spontaneously forms a natural, protective oxide layer. The powder further incorporates fibrous particles that absorb microwaves. The powder is heated to extrusion temperature by exposure to microwave energy.

Description

The invention relates to a method for producing a profile by extrusion of powder of metal and / or metal alloys, in which method a powder bed is heated to an extrusion temperature below the melting temperature of the powder and pressed under pressure through an opening of a die to the profile.

In the prior art, a billet is pressed as a metallic block material through the opening of a die in an extrusion press normally. In the extrusion of powdered materials, the powder beds are usually encapsulated in a container because of their low heat conduction prior to extrusion, and typically, e.g. by cold isostatic pressing, compacted. The poor heat conduction of the powder beds is made even more difficult by the oxide layers acting as an insulator on the metal particles. Due to the higher density and encapsulation during pressing, the heat transfer improves, and the entire powder bed can be heated by external heat homogeneously to the desired extrusion temperature, however, the time until the powder bed has set by heat conduction a uniform temperature distribution, relatively long is. For this reason, the direct processing of metallic powders in extrusion presses has not been successful.

The intended for extrusion powder bed must be brought as homogeneous as possible to the desired extrusion temperature. For this purpose, the powder bed according to the prior art is heated in a suitable container either inductively or in a convection oven. It is important to ensure that the heating process takes long enough to a possible ensure uniform temperature distribution within the powder bed. As a result of this long wait to ensure the temperature homogeneity occurs an undesirable delay in the production process. Furthermore, the risk of excessive heating in the outer surface layers of the bed and / or too long a heat treatment time increases. This is of particular importance when from at least two different components existing powder, so-called composite powder whose components at elevated temperature, either individually, eg by oxidation, or among themselves tend to undesirable reactions to be processed.

The prior art methods described above are, for example, in EP-A-0 327 064 . US-A-4,050,143 or US-A-4,699,657 disclosed.

The invention has for its object to provide a method of the type mentioned, with which a rapid and uniform heating in all areas of the powder bed can be achieved.

For solving the problem according to the invention, at least one metal or a metal alloy of the powder is a reactive metal which spontaneously forms a natural oxide protective layer on a free surface and / or the powder homogeneously contains fibrous particles which absorb microwaves, distributed in the bulk of the powder the powder bed is heated by microwave irradiation to extrusion temperature.

By using the microwave technique to heat the powder bed, a very rapid and very uniform heating in all areas of the powder bed is achieved due to their depth effect. This drastically shortens the waiting time until temperature homogeneity is reached. This applies in particular to reactive metallic powders, ie, to reactive metals spontaneously forming a natural oxide protective layer on a free surface such as aluminum, magnesium, titanium, tantalum or zirconium. These metallic powders have on their surface in principle a, albeit very thin, oxide layer, which, on the one hand, acts as an insulator on contact heat transfer, on the other hand, but supports the heating process by the microwaves. This is due to the fact that the cavities between the powder particles including the oxide layers act as so-called "wave guides" for the microwaves, since they correspond in dimension to the wavelength of the microwave radiation. As a result, the microwave radiation can penetrate unhindered and with multiple reflection the entire area of the powder bed homogeneous.

To optimize the penetration of the powder bed by the microwave radiation, the density of the powder bed or the dimension of the cavities between the powder particles including the oxide layers can be tuned by an appropriate compression of the powder bed in addition to the wavelength of the microwave radiation.

Now, when the powder, in addition to the metal particles, also absorbs microwave radiation energy absorbing fibrous components, such as e.g. Contains carbon nanotubes (CNTs), they act locally as receiving antennas or absorber for the microwave radiation. If the fibrous constituents are homogeneously distributed in the powder bed or, in the optimal case, even integrated at least partially into the metallic powder particles, a very effective and homogeneous heating of the entire bed can be achieved in this way. This effect can be enhanced by tuning the length of the fibrous components as closely as possible to the wavelength of the microwave radiation.

In a preferred embodiment of the method according to the invention, the powder bed, when heated to the extrusion temperature, is first irradiated with low microwave energy at a varying frequency and the absorbed energy is measured as a function of the frequency. At a certain frequency, the so-called resonance frequency, results in a maximum of the absorbed energy. With this frequency, the powder bed is now irradiated with high microwave energy, resulting in an effective Energieeinkoppelung.

The low frequency microwave sweep frequency sweep and the subsequent high microwave energy sweep at the resonant frequency to heat the powder bed to extrusion temperature can also be fully automated by control electronics so that the optimum frequency of injected microwave energy is always adjusted for different powder bulk and powder compositions.

In a further embodiment of the method according to the invention, the powder bed can first be precompressed, for example, by means of a screw conveyor in an intermediate container. Subsequently, the thus pre-compressed powder bed in the intermediate container is irradiated with the resonant frequency and thereby heated quickly and uniformly to extrusion temperature. By means of a punch the precompressed and heated to extrusion temperature powder bed is pressed out of the intermediate container through the die opening. In this way, a continuous extrusion of metallic powder material can be realized.

Claims (10)

Method for producing a profile by extrusion of powder of metal and / or metal alloys, in which method a powder bed is heated to an extrusion temperature below the melting temperature of the powder and pressed under pressure through an opening of a die to the profile,
characterized in that
in that at least one metal or a metal alloy of the powder is a reactive metal which spontaneously forms a natural oxide protective layer on a free surface and / or the powder homogeneously contains microwave-radiation-absorbing, fibrous particles distributed in the powder bed, and the powder bed is heated to an extrusion temperature by microwave irradiation becomes. A method according to claim 1, characterized in that the density of the powder bed or the dimension of the cavities between the powder particles including the oxide layers is tuned to the wavelength of the microwave radiation. A method according to claim 1 or 2, characterized in that the reactive metal spontaneously forming a natural oxide protective layer on a free surface is aluminum, magnesium, titanium, tantalum or zirconium. A method according to claim 1, characterized in that the length of the fibrous particles is tuned to the wavelength of the microwave radiation. A method according to claim 1 or 4, characterized in that the fibrous particles at least partially in the metallic powder particles are integrated. Method according to one of claims 1, 4 or 5, characterized in that the powder bed contains carbon nanotubes (CNTs) in a homogeneous distribution. Method according to one of claims 1 to 6, characterized in that the powder bed when heating to extrusion temperature initially irradiated with low microwave energy at changing frequency, the absorbed energy measured as a function of frequency and the resonance frequency is determined when a maximum of the absorbed energy occurs , And that subsequently the powder bed is irradiated with high microwave energy at the resonant frequency. A method according to claim 7, characterized in that the determination of the resonant frequency of the powder bed and the subsequent irradiation with high microwave energy is carried out fully automatically with the resonant frequency for heating the powder bed to extrusion by means of control electronics. A method according to claim 7 or 8, characterized in that the powder bed precompressed in an intermediate container, the precompressed powder bed in the intermediate container radiates through the resonant frequency and heated to extrusion temperature and is subsequently pressed by means of a punch from the intermediate container through the die opening. A method according to claim 9, characterized in that the precompression of the powder bed in the intermediate container is carried out with a screw conveyor.