DD283160A5 - HART METAL ALLOY - Google Patents

Abstract

The invention relates to a hard metal alloy, consisting of one or more hard material phases and a binding metal phase. The hard metal alloy according to the invention is particularly favorably applicable where, on the one hand, oxide-free and non-binder-metal depleted surfaces are necessary and, on the other hand, good mechanical properties are required. Typical applications are carbide-tipped mining tools, saw blades, cutting tools and press punches. The invention has for its object to develop a hard metal alloy, in which after completion of the carbide blank production a surface state is achieved, which has favorable conditions for soldering and other composite variants. This object is achieved according to the invention in that the starting powder mixture or the hard metal batch contains 0.5 to 5 *, preferably 1 * manganese or manganese oxide. It is expedient to include the addition of manganese as a master alloy with the binder metal in the starting powder mixture. Mining tools; saw blades; Cutting tools; Preszstempel; Oberflaechenzustand; Soldering; Manganese; manganese; Starting powder mixture}

Description

Field of application of the invention

The invention relates to a hard metal alloy consisting of one or more hard material phases and a binder metal phase. The hard material phase can WC oc'er other hard materials of the metals of IV., V. and Vl. Subgroup of the PSE or mixtures thereof. The binder metal phase consists of Co, Ni or Fe or of alloys of these metals, with the exception of austenitic binder metal alloys, and their content is 2.5-30% by weight of the heinmetal alloy.

The hard metal alloy according to the invention is particularly favorably applicable where, on the one hand, oxide-free and non-binder-metal-preheated surfaces are necessary and, on the other hand, a high level of mechanical properties such as hardness and fracture toughness are required. The hard metal alloy according to the invention is excellently suitable for the production of soldered joints z. As with steel, for the known coating methods and in the manufacture of sintered composites. Typical applications are carbide tipped mining tools, saw blades, cutting tools and press punches.

Characteristic of the known state of the art

Carbide blanks, due to their known powder metallurgy production process, which concludes with the sintering process, the hot isostatic I Jachverdichtungsverfahren or sintering / HIP Veifahren, a variety of Oberf'ächenzustände on. These may vary depending on the thermal processes, the protective atmospheres used, vacuums and cooling conditions.

Very often a binding metal depletion of the surface is observed. This occurs by evaporation of the binder metal during sintering and fühi time to the binding metal is removed to a layer thickness which can reach approximately the grain size of the hard material. Macroscopically, a matt gray appearance of the cemented carbide surface can be observed. Such a surface state has two essential wax parts. First, the crack dissolution from the surface is favored by the absence of the cement binder and the ability to readily detach hard grains, thereby significantly reducing the fracture toughness, flexing strength, and abrasive wear of such cemented carbide pieces. Second, such surfaces have poorer wettability to solder and impede diffusion processes, so that ultimately no optimum solder joints and other composite variations are achievable. In addition to the binder metal depletion of the cemented carbide surface, the non-targeted deposition of thin layers, in particular of oxide layers, frequently results in discoloration of the surfaces corresponding to the oxides which form. These layers also cause a significant reduction in solderability and have disturbing influences when using other composite variants.

These disadvantages have long been known and methods have been developed to avoid these disadvantages. These are chemical, thermal, chemo-thermal and electrolytic processes. Their purpose is, for example, to prevent binding metal depletion by electrolytic deposition of nickel or to remove oxide layers. Basically, these known treatment methods are additional operations that cause additional costs and are also harmful to the environment.

Further, in the production of sintered steel, it is known to prevent oxidation by the addition of manganese, so that the.en premixed manganese steel types can be sintered in a reducing atmosphere, eg, H2. However, the mechanisms involved are not comparable with the conditions for hard metals, because with hard metals in contrast to Sin. Rstahl the so-called liquid phase sintering is used to achieve the final density. In this case, the binder metal is from about 1300 ⁰ C in the liquid state and there occur solution and re-precipitation processes (Ostwald ripening) of the hard material phase.

EP-A 85125 describes a hard metal alloy, preferably for rock treatment, and the process for its production. Here are used as binder metal phase iron-nickel alloys that have an austenitic matrix, which partially convert to martensite under mechanical stress on the surface, whereby an increased hardness in the edge zone is achieved. This mechanism is favored by the addition of 5-20% Mn. The described in this invention improvements in fracture toughness and hardness of the / tandzone therefore rely on the formation of martensite as a result of mechanical stress btsirr ^one rock drilling wohöi the austenitic binder metal alloy and special manufacturing and Sinterbedingun.jen sen present need.

Object of the invention

It is the object of the invention to eliminate the disadvantages of the known hard metal alloys and to improve their properties for attachment by soldering or other composite variants.

Explanation of the essence of the invention

The invention has the object zugmnde to develop a hard metal alloy, in which after completion of the carbide blank production, a surface state is achieved, which has favorable conditions for soldering and other composite variants.

This object is achieved according to the present invention by virtue of the fact that the starting powder mixture or the hard metal batch contains 0.5 to 5% by weight, preferably 1% by weight, of manganese or manganese oxide.

It is expedient that the addition of manganese is included as a master alloy with the binder metal in the starting powder mixture.

Incidentally, the preparation of the hard metals according to the invention does not deviate from the usual method steps.

Regardless of the final sintering process, the hot isostatic densification or a pressure sintering process, the carbide blanks of hard metal alloys with the manganese addition according to the invention on a sample surface, which is favorable for soldering and other composite variants. In wetting tests with different Lotvarianten complete wetting was always achieved, which is often not the case with conventional carbide blank surfaces. With the Hartmtttallegierungen erfindunsgemäßen so optimal solder joints and other composite variants can be achieved without a post-treatment or a soldering under special conditions such. R. under vacuum is necessary.

In general, the effect according to the invention can already be recognized by the glossy appearance of the sintering surface.

embodiments Example 1:

With known process steps, such as Attritormahlung, spray drying, ng, pressing, outgassing under hydrogen and sintering in vacuo in parallel for the purpose of elimination of process effects two / VC-9.5% -Co-hard alloys, as they usually z. B. are used for impact drills, manufactured with and without Vln additive. The starting materials WC and Co as well as the plasticizer used were each from a Chargo.

The addition of manganese was carried out in the mixing batch in the form of pure μηO ₂ and indeed in an amount of 10 wt .-% Mn calculated on the binding metal.

In contrast to the sintering process for steel under H ₂ atmosphere described in patent EP-A 85125, in order to avoid Mn losses, here vacuum sintering is the most favorable in order to achieve the effect according to the invention.

After the vacuum sintering, a distinctly different appearance already appears. While the alloy 1 (without Mn additive) has a dull gray surface, the alloy 2 (with Mn additive) has a silvery shiny appearance. Accordingly, significant differences in wettability with commonly used solders are noticeable. Experiments to determine the shear forces necessary to destroy the solder joint resulted in an increase of up to 50%. In addition to these distinct advantages, there were still significant improvements in toughness properties.

The following table shows some properties of the two HM alloys with and without Mn addition.

Density in g / cm ³ hardness, HRA

Fracture toughness in MPa m 1/2 Flexural strength in MPa

Example 2:

A WC-9.5% Co-hard alloy was produced under the same conditions as in the 1st embodiment. However, the Mn addition was not carried out here in the form of MnO ₂ , but in the form of a Co-Mn master alloy. This was produced by melt metallurgy at a temperature of 1200 ⁰ C, subjected to a Voizerk in a jaw crusher and a milling in a ball mill. The Mn content of the master alloy was 60% by weight, thereby favoring pulverization. At lower Mn contents, difficulty is encountered in crushing the cast Co-Mn alloy.

In the end result, the same positive effects with regard to wettability with solder and thus the solderability as well as with regard to the mechanical properties could be achieved on these hard metal alloys according to the invention.

The erfindunsgemäßen carbide alloys of the Ausfuhrungso 1 + 2 are particularly suitable for the placement of Schlagbohrwerkzeugen for blasting drilling in ore mining and in the natural stone industry, but also for the placement of Schrämpicken for hard coal mining.

Example 3:

The Mn additives according to the invention were further tested on a WC-6% Co hardmetal alloy. Here, a Mn addition of 15% by weight to the binder metal was used.

The solderability of the saw teeth made from this carbide alloy for carbide-tipped circular saw blades equals that of electrolytically nickel-plated carbide sawteeth.

A further advantageous field of application of this hard metal alloy are drill plates for concrete drills, since in addition to the improved solderability, an increase in toughness also occurs in the case of this hardmetal alloy. With equal wear resistance, an increase in fracture toughness of about 10% has been demonstrated.

Example 4:

A WC-8.5% Co hardmetal alloy was prepared for example 1 according to the invention with 12% by weight of Mn additive. This alloy can be advantageous z. For example, as inserts for mining tools for rotary drilling of blast holes in the potash industry.

Alloy 1 Alloy 2 (without Mn addition) (with Mn addition) 14,50 14,50 87.0 37.0 17.0 19.0 1900 2300

Claims (2)

1. hard metal alloy consisting of one or more hard material phases of carbides of the metals of IV., V. and Vl. Subgroup of the PSE, preferably of tungsten carbide and a binder metal phase of cobalt, nickel or Eison or of alloys of these metals in a proportion of 2, £ his 30Ma .-%, excluding austenitic Bindemetallegierungen, characterized in that the starting powder mixture or the carbide 0, 5 to 5% by mass, preferably 1% by mass of manganese or manganese oxide. 2. Hartmetallegiorung according to claim 1, characterized in that the addition of manganese is contained as a master alloy with the binding metal and the starting powder mixture.