PT98195A - PROCESS FOR THE APPLICATION OF NITRIDE LAYERS ON TITANIUM - Google Patents

Abstract

An economical method for applying nitride layers to titanium and titanium alloys. In a short time, layer thicknesses of 20 mu m are achieved by nitriding under pressure in an ammonia atmosphere. Temperatures of 500 to 1000 DEG C and pressures of 0.2 to 10 Mpa are required for this purpose.

Description

Description relating to the patent of invention of BEGUSSA AKTIENGESELL SGHAFT, industrial and commercial, with headquarters in Weissfrauenstrasse 9, 1) -6000 FranKfurt am Maia,

Federal Republic of Germany, (inventor: Br, Friedrich Preisser, residing in the Federal Republic of Germany), for " PROCESS FOR APPLICATION AND NITRATE LAYERS ON "

The present invention relates to a process for applying layers of nitrides on titanium and titanium ligag parts by thermo-chemical treatment of those parts with ammonia or ammonia-containing gas mixtures under pressure and at temperatures above 500 ° C .

As a construction material, titanium has certain advantages over steel due to its specific gravity, corrosion resistance and high strength. To these characteristics is opposed to its relatively low hardness, which makes a surface treatment necessary when it is desired to increase the wear resistance. This surface treatment usually consists of the production of layers of titanium carbide or titanium nitrile. In the processes known up to now for nitrotion of parts of titanium or titanium alloys, we work with highly energetic gases or with electromagnetic fields. These processes are quite complex and can only be applied to parts with a simple geometry *

DE-PS 17 96 212 discloses - 1 -

titanium surface hardening by forming layers of nitrides in an atmosphere of ammonia at elevated temperatures and under normal pressure

Although, according to the claims, relatively thick and hard layers are formed, this process does not find application in practice 'because of the diffusion of hydrogen there is an increase in the fragility of the parts core.

In EP-OS 0 105 835 there is described a process for the preparation of nitride layers on titanium or titanium alloy parts, characterized in that the parts are introduced into an autoclave at pressures of 10 to 500 MPa and temperatures of 200 to 1200 ° C for example in an ammonia atmosphere. The ammonia used must be of high purity. The nitrosation is preferably 90-130 MPa, and at temperatures of 930-1000 ° C. This process has the disadvantage of being quite expensive due to the use of the autoclave and the high purity ammonia, and also to obtain layers having a thickness of 20 μm and after treatment periods of 3 hours and more.

It was therefore the object of the present invention to provide a process for the application of nitride layers on parts of titanium and titanium alloys by thermo-chemical treatment of those parts with ammonia or gaseous mixtures containing ammonia under pressure and at temperatures above 500 ° C , which would be economical and would make it possible to obtain nitride layers of 20 μm and more in relatively short time spans.

Such an object has been solved for the present invention by carrying out the treatment at a temperature of 500 to 100 ° C and under pressures of from 0.2 to 10 MPa maintaining the partial pressure of the ammonia at least 0.2 MPa.

Particularly advantageous were temperatures from 700 to 950 ° C and pressures of from 0.5 to 7 MPa, with partial pressure of ammonia of at least 0.2 MPa. - 2 -

Through this process the pressure can be coated with layers of sufficiently thick nitrides of 20 μm and more, titanium and titanium alloys of any size and geometry in the respective furnaces, are not necessarily required for such ultrapure gases, but sufficient ammonia quality normally marketed. In addition, it is possible to mix nitrogen into the ammonia and only a partial ammonia pressure of at least 0.2 MPa is required for the nitrosation process. The thickness of the titanium nitride layer formed depends, within the broad pressure limits, on the temperature and the treatment time. The surface becomes gilded shiny and results in a significant increase in hardness * Under pressures greater than 6 MPa and layer thickness is almost independent of the anticipation *

Figure 4 shows the formation of a layer of titanium nitride on parts of pure titanium as a function of the pressure and temperature of the ammonia-containing atmosphere.

Then at temperatures of, for example, 500 ° C, absolute pressure of 2 MPa (** 20 bar) was measured and after one hour a TiN layer thickness of 10 μm, at 880 ° C was prepared for this time a pure TiN layer of 20 pm * At a pressure of 6 MPa (* 60 bar) a TiN layer of, for example, 30æum is prepared if the samples are kept for one hour at 880øC.

Increased pressure up to 9 MPa (* 90 bar) further decreases the influence of pressure on the TiN layer thickness. Its increase is not linear. Under still higher pressures, only the diffusion of the nitrogen through the layer becomes the determinant of time, given the rapid formation of a dense layer of TiN *

Like pure titanium, titanium alloys, such as, for example, T1A16V4, may also be nitrosated.

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Claims (1)

For the deposition of this coating, no autoclaving is necessary and the treatment can be carried out in the usual chamber furnaces. Ia - Process for applying layers of nitrides on titanium and titanium alloys by thermo-chemical treatment of these parts with ammonia or gas mixtures containing ammonia under pressure and at temperatures above 500 ° C, characterized in that the treatment is carried out at temperatures of 500 to 1000 ° C and under pressures of 0.2 to 10 MPa, maintaining the partial pressure of ammonia at at least 0.2 MPa. A process for applying nitride layers according to claim 1, characterized in that the treatment is carried out at temperatures of 700 to 950 ° C and under pressures of 0.5 to 7 MPa, while maintaining The partial pressure of ammonia is at least 0.2 MPa. The applicant claims the priority of the German application filed on July 4, 1990, under P, P140 21 286.6-45. Lisbon, 03 July 1991 - 4 -