EP0455005A1 - High temperature alloy for engine components, based on modified titanium aluminide - Google Patents

Abstract

The high-temperature alloy is intended for mechanically and thermally highly stressed components of machines. It is based essentially on doped TiAl and has the following composition: TixElyMezAl1-(x + y + z), with El = B, Ge or Si and Me = Co, Cr, Ge, Hf, Mn, Mo, Nb, Pd, Ta, V, W, Y and/or Zr and with the following relationships: 0.46 </= x             </= 0.54, 0.001 </= y            </= 0.015 for El = Ge and Me = Cr, Hf, Mn, Mo,                      Nb, Ta, V and/or W, 0.001 </= y            </= 0.015 for El = Si and Me = Hf, Mn, Mo, Ta, V                      and/or W, 0 </= y                </= 0.01 for El = B and Me = Co, Ge, Pd, Y and/or                      Zr, 0 </= y                </= 0.02 for El = Ge and Me = Co, Ge, Pd, Y and/or                      Zr, 0.0001 </= y           </= 0.01 for El = B and Me = Cr, Mn, Nb and/or W, 0.01 </= z             </= 0.04, if Me = a single element, 0.01 </= z             </= 0.08, if Me = two or more single elements and 0.46 </= (x + y + z)   </= 0.54. <IMAGE>

Description

High-temperature alloys for thermal machines based on intermetallic compounds, which are suitable for directional solidification and complement the conventional nickel-based superalloys.

The invention relates to the further development and improvement of the alloys based on an intermetallic compound of the titanium aluminide TiAl type with further additives which increase strength, toughness and ductility.

In the narrower sense, the invention relates to a high-temperature alloy for machine components based on doped TiAl.

STATE OF THE ART

Intermetallic compounds of titanium with aluminum have some interesting properties which make them appear attractive as construction materials in the medium and higher temperature range. Among other things, this includes their low density compared to superalloys, which is only approx. 1/2 of the value for Ni superalloys reached. However, their technical usability in the present form stands in the way of their brittleness. The former can be improved by additives, whereby higher strength values are also achieved. As possible and in part already introduced intermetallic compounds, inter alia nickel aluminides, nickel silicides and titanium aluminides are known as construction materials.

Attempts have already been made to improve the properties of pure TiAl by slight changes in the Ti / Al atomic ratio and by alloying with other elements. Cr, B, V, Si, Ta, as well as (Ni + Si) and (Ni + Si + B), as well as Mn, W, Mo, Nb, Hf, were proposed as further elements, for example. The intention was, on the one hand, the brittleness to reduce, ie to increase the ductility and toughness of the material, on the other hand to achieve the highest possible strength in the temperature range of interest between room temperature and operating temperature. A sufficiently high resistance to oxidation was also sought. However, these goals were only partially achieved.

However, the heat resistance of the known aluminides still leaves something to be desired. Corresponding to the comparatively low melting point of these materials, the strength, in particular the creep resistance in the upper temperature range, is inadequate, as is also apparent from publications in this regard.

From US-A-3 203 794 a TiAl high-temperature alloy with 37% by weight Al, 1% by weight Zr, the rest Ti is known. The comparatively small addition of Zr means that this alloy has comparable properties to pure TiAl.

EP-A1-0 365 598 shows a high-temperature alloy based on TiAl with additions of Si and Nb, whereas EP-A1-0 405 134 suggests a high-temperature alloy based on TiAl with additions of Si and Cr.

• N.S. Stoloff, "Ordered alloys-physical metallurgy and structural applications", International metals review, Vol. 29, No. 3, 1984, pp. 123-135.
• G. Sauthoff, "Intermetallische Phasen", Werkstoffe zwischen Metall und Keramik, Magazin neue Werkstoffe 1/89, S.15-19.
• Young-Won Kim, "Intermetallic Alloys based on Gamma Titanium Aluminide", JOM, July 1989.
• US-A-4 842 817
  US-A-4 842 819
  US-A-4 842 820
• US-A-4 857 268
  US-A-4 836 983
  EP-A-0 275 391

The following documents relating to the prior art are also cited:

• NS Stoloff, "Ordered alloys-physical metallurgy and structural applications", International metals review, Vol. 29, No. 3, 1984, pp. 123-135.
• G. Sauthoff, "Intermetallic phases", materials between metal and ceramic, magazine new materials 1/89, p.15-19.
• Young-Won Kim, "Intermetallic Alloys based on Gamma Titanium Aluminide", JOM, July 1989.
• US-A-4 842 817
  US-A-4 842 819
  US-A-4 842 820
• US-A-4 857 268
  US-A-4,836,983
  EP-A-0 275 391

The properties of the known modified intermetallic compounds generally do not yet meet the technical requirements in order to produce usable workpieces therefrom. This applies in particular to heat resistance and toughness (ductility). There is therefore a need for further development and improvement of such materials.

PRESENTATION OF THE INVENTION

The invention, as defined in the single patent claim, is based on the object of specifying a light alloy with adequate oxidation and corrosion resistance at high temperatures and at the same time high heat resistance and sufficient toughness in the temperature range from 500 to 1000 ° C., which is good for directed Solidification is suitable and essentially consists of a high-melting intermetallic compound.

WAY OF CARRYING OUT THE INVENTION

The invention is described on the basis of the following exemplary embodiments which are explained in more detail by means of figures.

Fig. 1-4

graphische Darstellungen der Vickershärte HV in Funktion der Temperatur von Legierungen 3-9, 14-20, 21-27 und 33-38 auf der Basis der intermetallischen Verbindung Titanaluminid, sowie von Vergleichslegierungen 1 und 2,

Fig. 5-8

graphische Darstellungen der Fliessgrenze σ_0,2 in Funktion der Temperatur von den Legierungen 3-9, 14-20, 21-27 und 33-39 sowie von den Vergleichslegierungen 1 und 2, und

Fig. 9-11

graphische Darstellungen des Einflusses von Wolframzusätzen auf die Vickershärte HV und die Bruchdehnung δ bei Raumtemperatur von Legierungen 11-13, 28-32, 40 und 41 auf der Basis der intermetallischen Verbindung Titanaluminid.

Show:

Fig. 1-4

graphical representations of the Vickers hardness HV as a function of the temperature of alloys 3-9, 14-20, 21-27 and 33-38 based on the intermetallic compound titanium aluminide, as well as comparative alloys 1 and 2,

Fig. 5-8

graphical representations of the yield point σ _0.2 as a function of the temperature of alloys 3-9, 14-20, 21-27 and 33-39 as well as of comparative alloys 1 and 2, and

Fig. 9-11

graphical representations of the influence of tungsten additives on the Vickers hardness HV and the elongation at break δ at room temperature of alloys 11-13, 28-32, 40 and 41 based on the intermetallic compound titanium aluminide.

Legierung 1:

50 At.-% Ti, Rest Al

Legierung 2:

52 At.-% Ti, Rest Al

Legierung 3:

48,5 At.-% Ti, 3 At.-% W, 0,5 At.-% Ge, 48 At.-% Al

Legierung 4:

50,5 At.-% Ti, 3 At.-% W, 0,5 At.-% Ge, 46 At.-% Al

Legierung 5:

48,5 At.-% Ti, 3 At.-% W, 0,5 At.-% Si, 48 At.-% Al

Legierung 6:

47,5 At.-% Ti, 4 At.-% W, 0,5 At.-% Si, 48 At.-% Al

Legierung 7:

48,5 At.-% Ti, 3 At.-% Cr, 0,5 At.-% Ge, 48 At.-% Al

Legierung 8:

48,5 At.-% Ti, 3 At.-% Ta, 0,5 At.-% Ge, 48 At.-% Al

Legierung 9:

48,5 At.-% Ti, 3 At.-% Ta, 0,5 At.-% Si, 48 At.-% Al

Fig. 1 is a graphical representation of the Vickers hardness HV (kg / mm₂) as a function of the temperature T (° C) of alloys 3-9 based on the intermetallic compound titanium aluminide. In order to be able to see the influence of the alloy elements, the Vickers hardnesses for the pure titanium aluminides 1 and 2 with 50 at.% Al and with 48 at.% Al are shown. The alloys have the following composition:

Alloy 1:

50 at.% Ti, balance Al

Alloy 2:

52 at% Ti, balance Al

Alloy 3:

48.5 at.% Ti, 3 at.% W, 0.5 at.% Ge, 48 at.% Al

Alloy 4:

50.5 at.% Ti, 3 at.% W, 0.5 at.% Ge, 46 at.% Al

Alloy 5:

48.5 at.% Ti, 3 at.% W, 0.5 at.% Si, 48 at.% Al

Alloy 6:

47.5 at.% Ti, 4 at.% W, 0.5 at.% Si, 48 at.% Al

Alloy 7:

48.5 at.% Ti, 3 at.% Cr, 0.5 at.% Ge, 48 at.% Al

Alloy 8:

48.5 at.% Ti, 3 at.% Ta, 0.5 at.% Ge, 48 at.% Al

Alloy 9:

48.5 at.% Ti, 3 at.% Ta, 0.5 at.% Si, 48 at.% Al

The curves all show a similar characteristic course. Up to a temperature of approx. 500 ° C, an average drop of 10% must be expected. At 700 ° C the hardness HV is still approx. 80%, at 850 ° C approx. 70% of the value at room temperature.

Legierung 1:

50 At.-% Ti, Rest Al

Legierung 2:

52 At.-% Ti, Rest Al

Legierung 14:

50 At.-% Ti, 2 At.-% Y, 48 At.-% Al

Legierung 15:

49 At.-% Ti, 3 At.-% Y, 48 At.-% Al

Legierung 16:

49 At.-% Ti, 3 At.-% Ge, 48 At.-% Al

Legierung 17:

49 At.-% Ti, 3 At.-% Pd, 48 At.-% Al

Legierung 18:

50 At.-% Ti, 2 At.-% Co, 48 At.-% Al

Legierung 19:

51 At.-% Ti, 1 At.-% Zr, 48 At.-% Al

Legierung 20:

49 At.-% Ti, 3 At.-% Zr, 48 At.-% Al

Fig. 2 is a graphical representation of the Vickers hardness HV (kg / mm₂) as a function of the temperature T (° C) of alloys 14-20 based on the intermetallic compound titanium aluminide, and of comparative alloys 1 and 2.

Alloy 1:

50 at.% Ti, balance Al

Alloy 2:

52 at% Ti, balance Al

Alloy 14:

50 at.% Ti, 2 at.% Y, 48 at.% Al

Alloy 15:

49 at.% Ti, 3 at.% Y, 48 at.% Al

Alloy 16:

49 at.% Ti, 3 at.% Ge, 48 at.% Al

Alloy 17:

49 at.% Ti, 3 at.% Pd, 48 at.% Al

Alloy 18:

50 at.% Ti, 2 at.% Co, 48 at.% Al

Alloy 19:

51 at.% Ti, 1 at.% Zr, 48 at.% Al

Alloy 20:

49 at.% Ti, 3 at.% Zr, 48 at.% Al

The curves all show a similar characteristic course. Up to a temperature of approx. 500 ° C, an average drop of 10% must be expected. At 700 ° C the hardness HV is still approx. 80%, at 850 ° C approx. 70% of the value at room temperature.

Legierung 21:

48,5 At.-% Ti, 3 At.-% Y, 0,5 At.-% B, 48 At.-% Al

Legierung 22:

47 At.-% Ti, 3 At.-% Zr, 2 At.-% Ge, 48 At.-% Al

Legierung 23:

48,5 At.-% Ti, 3 At.-% Y, 0,5 At.-% Ge, 48 At.-% Al

Legierung 24:

50,5 At.-% Ti, 1 At.-% Zr, 0,5 At.-% Ge, 48 At.-% Al

Legierung 25:

48,5 At.-% Ti, 3 At.-% Zr, 0,5 At.-% Ge, 48 At.-% Al

Legierung 26:

48,5 At.-% Ti, 3 At.-% Pd, 0,5 At.-% Ge, 48 At.-% Al

Legierung 27:

48,5 At.-% Ti, 3 At.-% Co, 0,5 At.-% Ge, 48 At.-% Al

FIG. 3 relates to the graphical representation of the Vickers hardness HV as a function of the temperature T of alloys 21-27 based on the intermetallic compound titanium aluminide, and of the comparative alloys 1 and 2.

Alloy 21:

48.5 at.% Ti, 3 at.% Y, 0.5 at.% B, 48 at.% Al

Alloy 22:

47 at.% Ti, 3 at.% Zr, 2 at.% Ge, 48 at.% Al

Alloy 23:

48.5 at.% Ti, 3 at.% Y, 0.5 at.% Ge, 48 at.% Al

Alloy 24:

50.5 at.% Ti, 1 at.% Zr, 0.5 at.% Ge, 48 at.% Al

Alloy 25:

48.5 at.% Ti, 3 at.% Zr, 0.5 at.% Ge, 48 at.% Al

Alloy 26:

48.5 at.% Ti, 3 at.% Pd, 0.5 at.% Ge, 48 at.% Al

Alloy 27:

48.5 at.% Ti, 3 at.% Co, 0.5 at.% Ge, 48 at.% Al

The statements made under Fig. 2 apply.

Legierung 1:

50 At.-% Ti, Rest Al

Legierung 2:

52 At.-% Ti, Rest Al

Legierung 33:

50,5 At.-% Ti, 1 At.-% W, 0,5 At.-% B, 48 At.-% Al.

Legierung 34:

48,5 At.-% Ti, 3 At.-% W, 0,5 At.-% B, 48 At.-% Al.

Legierung 35:

48 At.-% Ti, 3 At.-% W, 1 At.-% B, 48 At.-% Al.

Legierung 36:

49,5 At.-% Ti, 2 At.-% Mn, 0,5 At.-% B, 48 At.-% Al.

Legierung 37:

48,5 At.-% Ti, 3 At.-% Cr, 0,5 At.-% B, 48 At.-% Al.

Legierung 38:

47,5 At.-% Ti, 2 At.-% Mn, 2 At.-% Nb, 0,5 At.-% B, 48 At.-% Al.

Legierung 39:

48,5 At.-% Ti, 2 At.-% Cr, 1 At.-% Mn, 0,5 At.-% B, 48 At.-% Al.

4 is a graphical representation of the Vickers hardness HV (kg / mm 2) as a function of the temperature T (° C.) of alloys 33-39 based on the intermetallic compound titanium aluminide and of comparative alloys 1 and 2.

Alloy 1:

50 at.% Ti, balance Al

Alloy 2:

52 at% Ti, balance Al

Alloy 33:

50.5 at.% Ti, 1 at.% W, 0.5 at.% B, 48 at.% Al.

Alloy 34:

48.5 at.% Ti, 3 at.% W, 0.5 at.% B, 48 at.% Al.

Alloy 35:

48 at.% Ti, 3 at.% W, 1 at.% B, 48 at.% Al.

Alloy 36:

49.5 at.% Ti, 2 at.% Mn, 0.5 at.% B, 48 at.% Al.

Alloy 37:

48.5 at.% Ti, 3 at.% Cr, 0.5 at.% B, 48 at.% Al.

Alloy 38:

47.5 at.% Ti, 2 at.% Mn, 2 at.% Nb, 0.5 at.% B, 48 at.% Al.

Alloy 39:

48.5 at.% Ti, 2 at.% Cr, 1 at.% Mn, 0.5 at.% B, 48 at.% Al.

The curves all show a similar characteristic course. Up to a temperature of approx. 500 ° C, an average drop of 10% must be expected. At 700 ° C the hardness HV is still approx. 80%, at 850 ° C approx. 70% of the value at room temperature.

5 is a graphical representation of the yield point σ _0.2 (MPa) as a function of temperature T (° C) of alloys 1-9.

All curves show a similar behavior of the material. Up to a temperature of approx. 900 ° C the yield point initially decreases more, then less strongly to approx. 80% of the value at room temperature. From approx. 1000 ° C (above the knee of the curve) the steep drop to low values occurs.

6 is a graphical representation of the yield point σ _0.2 (MPa) as a function of temperature T (° C.) of alloys 14-20 and of comparative alloys 1 and 2.

All curves show a similar behavior of the material. Up to a temperature of approx. 900 ° C the yield point initially decreases more, then less strongly to approx. 80% of the value at room temperature. From approx. 1000 ° C (above the knee of the curve) the steep drop then takes place at low values.

FIG. 7 relates to a graphic representation of the yield point σ _0.2 as a function of the temperature of alloys 21-27 and of comparative alloys 1 and 2.

The statements made under Fig. 3 apply.

8 is a graphical representation of the yield point σ _0.2 (MPa) as a function of temperature T (° C.) of alloys 33-39 and comparative alloys 1 and 2.

All curves show a similar behavior of the material. Up to a temperature of approx. 900 ° C the yield point initially decreases more, then less strongly to approx. 80% of the value at room temperature. From approx. 1000 ° C (above the knee of the curve) the steep drop then takes place at low values.

FIGS. 9, 10 and 11 each relate to graphic representations of the influence of metal additives (Me, W) on the mechanical properties of alloys based on the intermetallic compound titanium aluminide at room temperature. For alloys 11, 12, 13, 28, 29, 30, 40 and 41, the influence of tungsten and yttrium content on the Vickers hardness is HV (kg / mm²) and for alloys 11, 12, 13, 31, 32 and 40 the influence of the tungsten or xttrium content on the elongation at break δ (%) each at room temperature.

The alloy 11 serves as the basis. The alloy compositions are as follows:

With increasing metal content Me (Me = W, Y, Zr), a considerable increase in hardness can be determined with a comparatively slight decrease in the elongation at break. The ductile effect of the boron addition is particularly striking.

Example 1:

An alloy of the following composition was melted in an arc furnace under argon as a protective gas:
Ti = 51 at .-%
Si = 0.2 at%
W = 4 at%
Al = 44.8 at%

The individual elements with a purity of 99.99% served as the starting materials. The melt was poured into a cast blank of approximately 50 mm in diameter and approximately 70 mm in height. The blank was melted again under protective gas and also forced under solidification to solidify in the form of rods with a diameter of approximately 9 mm and a length of approximately 70 mm.

The bars were processed directly into pressure samples for short-term tests without subsequent heat treatment.

A further improvement of the mechanical properties through a suitable heat treatment is within the realms of possibility. There is also the possibility of improvement by directional solidification, for which the alloy is particularly suitable.

Example 2 :

Analogously to Example 1, the following alloy was melted under argon:
Ti = 51 at .-%
Si = 0.5 at .-%
Mo = 3.5 at .-%
Al = 45 at%

The melt was poured off analogously to embodiment 1, melted again under argon and forced to solidify in the form of a rod. The dimensions of the rods corresponded to embodiment 1. The rods were processed directly into pressure samples without subsequent heat treatment. The mechanical properties as a function of the test temperature thus approximately corresponded to those of Example 1. These values can be further improved by heat treatment.

Example 3:

Exactly the same as in Example 1, the following alloy was melted under an argon atmosphere:
Ti = 50 at%
Si = 0.8 at%
V = 3 at .-%
Al = 46.2 at%

The melt was poured off analogously to Example 1, melted again under argon and cast into prisms of square cross section (7 mm × 7 mm × 80 mm). Test specimens for pressure, hardness and impact tests were produced from these prisms. The mechanical properties corresponded approximately to those of the previous examples. Heat treatment resulted in a further improvement in these values.

Embodiments 4-21:

The following alloys were melted under argon:
Ti = 50 at%
Ge = 1.4 at%
Mn = 1.6 at .-%
Al = 47 at%
Ti = 48 at%
Ge = 1 at%
Mn = 2 at%
Al = 49 at%
Ti = 51 at .-%
Ge = 0.6 at.%
Ta = 3 at .-%
Al = 45.4 at%
Ti = 46 at%
Ge = 0.1 at%
Hf = 4 at%
Al = 49.9 at%
Ti = 51 at .-%
Si = 1.5 at%
W = 2 at%
Mn = 1.5 at%
Al = 44 at%
Ti = 50 at%
Si = 1 atom%
V = 1.5 at%
Cr = 2.5 at .-%
Al = 45 at%
Ti = 48 at%
Si = 0.5 at .-%
Ta = 3 at .-%
Nb = 1 atom%
Al = 47.5 at .-%
Ti = 46 at%
Si = 0.1 at%
Mo = 2.5 at%
Hf = 1.5 at%
Al = 49.9 at%
Ti = 51.5 at .-%
Ge = 0.2 at%
W = 1 atom%
V = 3 at .-%
Al = 44.3 at%
Ti = 50 at%
Ge = 0.8 at .-%
Mn = 2.4 at.%
Cr = 1.6 at .-%
Al = 45.2 at%
Ti = 47 at%
Ge = 1.3 at%
Nb = 2.5 at%
Hf = 0.5 at .-%
Al = 48.7 at%
Ti = 47 at%
Si = 0.3 at%
W = 1.5 at%
Cr = 1 atom%
Nb = 1 atom%
Al = 49.2 at%
Ti = 51 at .-%
Si = 0.7 at%
Mo = 0.7 at.%
Mn = 3 at%
V = 0.3 at%
Al = 44.3 at%
Ti = 50 at%
Si = 1 atom%
V = 1 atom%
Nb = 1 atom%
Mn = 1 atom%
Al = 45 at%
Ti = 49 at%
Si = 1.2 at%
Ta = 1.5 at%
W = 1.4 at%
Hf = 1 atom%
Al = 45.9 at%
Ti = 49 at%
Ge = 1.5 at%
W = 2.5 at%
Mo = 0.5 at .-%
Cr = 1 atom%
Al = 45.5 at%
Ti = 51.5 at .-%
Ge = 1 atom%
V = 1.5 at%
Ta = 0.5 at .-%
Hf = 1.5 at%
Al = 44 at%
Ti = 46 at%
Ge = 0.5 at .-%
Nb = 3 at%
Mo = 0.5 at .-%
Cr = 0.5 at .-%
Al = 49.5 at .-%

Otherwise, the procedure was as in Example 1.

Example 22:

Exactly the same as in Example 1, alloy 3 was melted under an argon atmosphere:
Ti = 48.5 at .-%
Ge = 0.5 at .-%
W = 3 at%
Al = 48 at .-%

The melt was poured off analogously to Example 1, melted again under argon and cast into prisms of square cross section (7 mm × 7 mm × 80 mm). Test specimens for pressure, hardness and impact tests were produced from these prisms. The course of the mechanical properties corresponded approximately to that of the previous examples. The yield point σ _0.2 at room temperature was 582 Mpa. The course over the temperature T is indicated in FIG. 5. Alloy 1 (pure TiAl) is shown as a reference. The Vickers hardness HV at room temperature averaged 322 units. The course over the temperature T is shown in FIG. 1. Alloy 1 (pure TiAl) is to be given as the reference quantity. Heat treatment further improved these values.

Embodiment 23:

Alloy 4 was melted from the pure elements in accordance with Example 22:
Ti = 50.5 at .-%
Ge = 0.5 at .-%
W = 3 at%
Al = 46 at%

The yield point σ _0.2 at room temperature was 553 MPa. The course over the temperature T is shown in FIG. 5. The Vickers hardness HV at room temperature averaged 335 units. Their course over the temperature T is indicated in Fig. 1. Embodiment 24:

According to Example 22, the alloy 5 was melted from the pure elements:
Ti = 48.5 at .-%
Si = 0.5 at .-%
W = 3 at%
Al = 48 at .-%

The yield point σ _0.2 at room temperature was 578 MPa. The course of the flow limit over the temperature T is plotted in FIG. 5. The Vickers hardness HV at room temperature reached 350 units. Their course over the temperature T is recorded in Fig. 1. The hardness-increasing effect of the combined W and Si additives compared to pure TiAl must be noted. In the present case, it averages 75%.

Embodiment 25:

According to Example 22, alloy 6 was melted from pure elements:
Ti = 47.5 at .-%
Si = 0.5 at .-%
W = 4 at%
Al = 48 at .-%

The yield point σ _0.2 at room temperature was 572 MPa (Fig. 5). The Vickers hardness HV reached the value of 347 units at room temperature (FIG. 1).

Embodiment 26:

The procedure was exactly the same as in Example 22. The molten alloy 7 had the following composition:
Ti = 48.5 at .-%
Ge = 0.5 at .-%
Cr = 3 at .-%
Al = 48 at .-%

The yield point σ _0.2 at room temperature was 550 MPa (Fig. 5). The Vickers hardness HV at room temperature averaged 333 units (Fig. 1).

Embodiment 27:

According to Example 22, the following alloy 8 was melted from the pure elements:
Ti = 48.5 at .-%
Ge = 0.5 at .-%
Ta = 3 at .-%
Al = 48 at .-%

The yield point σ _0.2 at room temperature reached 495 MPa (Fig. 5). The Vickers hardness HV at room temperature averaged 300 units (FIG. 1).

Embodiment 28:

According to Example 22, alloy 9 of the following composition was melted from the pure elements:
Ti = 48.5 at .-%
Si = 0.5 at .-%
Ta = 3 at .-%
Al = 48 at .-%

A yield point σ _0.2 at room temperature of 461 MPa was reached (Fig. 5). The Vickers hardness HV at room temperature was 279 units (Fig. 1).

Embodiment 29:

An alloy with the following composition was melted in an oven in accordance with Example 22:
Ti = 48.5 at .-%
Si = 0.5 at .-%
V = 3 at .-%
Al = 48 at .-%

The yield point σ _0.2 at room temperature was 489 MPa. Their course over the temperature T is similar to that of alloy 8. The Vickers hardness HV at room temperature was 296 units. It had a profile similar to alloy 8 over temperature.

Embodiment 30:

Similar to Example 22, the following alloy was melted from the elements:
Ti = 47.5 at .-%
Ge = 0.5 at .-%
Mn = 2 at%
Nb = 2 at%
Al = 48 at .-%

At room temperature, the yield point σ _{0.2 was} approx. 478 MPa. The course over the temperature lies approximately in the middle between the corresponding courses of alloys 8 and 9. The Vickers hardness HV was 290 units at room temperature. Their temperature profile lies approximately in the middle between the corresponding temperature profiles of alloys 8 and 9.

Embodiment 31:

According to Example 22, an alloy of the following composition was melted:
Ti = 48.5 at .-%
Ge = 0.5 at .-%
Nb = 3 at%
Al = 48 at .-%

The yield point σ was _0.2 388 MPa at room temperature. Their course over the temperature T practically coincides with that of the alloy 2. The Vickers hardness HV at room temperature reached 235 units. The corresponding course over T practically coincides with that of alloy 2.

Embodiment 32:

An alloy of the following composition was melted from the pure elements in an oven under protective gas:
Ti = 49.5 at .-%
Si = 0.5 at .-%
Mn = 2 at%
Al = 48 at .-%

The yield point σ _0.2 at room temperature was measured at 449 MPa. Their course over the temperature T is just below that of the alloy 9. The Vickers hardness HV at room temperature gave a value of 272 units. The temperature profile is just below that of alloy 9.

Embodiment 33:

According to Example 22, the following alloy was melted under protective gas:
Ti = 44.5 at .-%
Ge = 0.5 at .-%
W = 3 at%
Al = 52 at%

The yield point σ _0.2 at room temperature gave an average value of 522 MPa. Their temperature profile is just below that of alloy 3. The Vickers hardness HV at room temperature was 316 units. The corresponding course over the temperature T is just below that of the alloy 3.

Example 34:

An alloy of the following composition was melted in the arc furnace under argon as a protective gas:
Ti = 47 at%
Y = 3.5 at%
Al = 49.5 at .-%

The individual elements with a purity of 99.99% served as the starting materials. The melt was poured into a cast blank of approximately 60 mm in diameter and approximately 80 mm in height. The blank was melted again under protective gas and also forced under solidification to solidify in the form of rods with a diameter of approximately 8 mm and a length of approximately 80 mm.

The bars were processed directly into pressure samples for short-term tests without subsequent heat treatment. The mechanical properties achieved were measured as a function of the test temperature.

A further improvement of the mechanical properties through a suitable heat treatment is within the realms of possibility. There is also the possibility of improvement by directional solidification, for which the alloy is particularly suitable.

Embodiment 35:

The following alloy was melted under argon as in Example 34:
Ti = 52 at%
Co = 1 atom%
Al = 47 at%

The melt was poured off analogously to embodiment 34, melted again under argon and forced to solidify in the form of a rod. The dimensions of the rods corresponded to embodiment 34. The rods were processed directly into pressure samples without subsequent heat treatment. The mechanical properties as a function of the test temperature thus achieved corresponded approximately to those of Example 34. These values can be further improved by heat treatment.

Embodiment 36:

Exactly the same as in Example 34, the following alloy was melted under an argon atmosphere:
Ti = 50 at%
Zr = 2.5 at%
Al = 47.5 at .-%

The melt was poured off as in Example 34, melted again under argon and cast into prisms of square cross section (8 mm × 8 mm × 100 mm). Test specimens for pressure, hardness and impact tests were produced from these prisms. The mechanical properties corresponded approximately to those of the previous examples. Heat treatment further improved these values.

Examples 37-46:

The following alloys were melted under argon:
Ti = 46 at%
Ge = 2 at%
Al = 52 at%
Ti = 48 at%
Pd = 0.5 at .-%
Al = 51.5 at%
Ti = 48 at%
Zr = 4 at%
B = 1.5 at%
Al = 46.5 at%
Ti = 47 at%
Y = 3 at .-%
B = 1 atom%
Al = 49 at%
Ti = 48 at%
Co = 3 at .-%
B = 1 atom%
Al = 48 at .-%
Ti = 50 at%
Pd = 0.2 at.%
B = 0.8 at .-%
Al = 49 at%
Ti = 47.5 at .-%
Y = 1.5 at .-%
Ge = 0.5 at .-%
Al = 50.5 at%
Ti = 50 at%
Co = 2 at .-%
Ge = 2 at%
Al = 46 at%
Ti = 47 at%
Zr = 1 atom%
Ge = 1.5 at%
Al = 50.5 at%
Ti = 52 at%
Pd = 0.3 at.%
Ge = 0.5 at .-%
Al = 47.2 at%

Samples for determining hardness, elasticity and the yield point were produced.

Embodiment 47:

Alloy 14 was melted in a small furnace under argon as a protective gas, starting from the pure elements:
Ti = 50 at%
Y = 2 at%
Al = 48 at .-%

After the blank had been melted, small samples were cast to determine the hardness and the yield point as well as the ductility. The rods were 6 mm in diameter and 60 mm long. The yield point σ _0.2 at room temperature was 582 MPa. The course over the temperature T is indicated in FIG. 6 according to curve 14. The temperature profile of alloy 1 (pure TiAl) is drawn in as a reference variable. The Vickers hardness HV at room temperature averaged 352 units. The course over the temperature T is shown in FIG. 2. Alloy 1 (pure TiAl) is again given as the reference quantity.

Example 48:

Alloy 15 was melted from the pure elements in accordance with Example 47:
Ti = 49 at%
Y = 3 at .-%
Al = 48 at .-%

The yield point σ _0.2 at room temperature was 650 MPa (Fig. 6). The Vickers hardness HV at room temperature averaged 394 units (FIG. 2). The hardness-increasing effect of the Y addition compared to pure TiAl is remarkable and is almost 100%.

Embodiment 49:

According to Example 47, the alloy 16 was melted from the pure elements:
Ti = 49 at%
Ge = 3 at%
Al = 48 at .-%

The yield point σ _0.2 at room temperature was 482 MPa (Fig. 6). The Vickers hardness HV at room temperature reached the value of 292 units (Fig. 2).

Embodiment 50:

According to Example 47, alloy 17 was melted from pure elements:
Ti = 49 at%
Pd = 3 at .-%
Al = 48 at .-%

The yield point σ _0.2 at room temperature was 512 MPa (Fig. 6). The Vickers hardness HV reached the value of 310 units at room temperature (FIG. 2).

Embodiment 51:

The procedure was exactly the same as in Example 47. The molten alloy 18 had the following composition:
Ti = 50 at%
Co = 2 at .-%
Al = 48 at .-%

The yield point σ _0.2 at room temperature was 426 MPa (Fig. 6). The Vickers hardness HV at room temperature averaged 258 units (Fig. 2).

Example 52:

According to Example 17, alloy 19 of the following composition was melted:
Ti = 51 at .-%
Zr = 1 atom%
Al = 48 at .-%

The yield point σ _0.2 at room temperature was 439 MPa (Fig. 6). The Vickers hardness HV at room temperature reached an average of 266 units (FIG. 2).

Example 53:

According to Example 47, the following alloy 20 was melted from the pure elements:
Ti = 49 at%
Zr = 3 at .-%
Al = 48 at .-%

The yield point σ _0.2 at room temperature reached 512 MPa (Fig. 6). The Vickers hardness HV at room temperature averaged 310 units (FIG. 2). The hardness-increasing effect of the Zr addition compared to alloy 1 (pure TiAl) is therefore approx. 55%.

Example 54:

According to Example 47, alloy 21 of the following composition was melted from the pure elements:
Ti = 48 at%
B = 0.5 at%
Y = 3 at .-%
Al = 48 at .-%

A yield point σ _0.2 of 645 MPa was reached at room temperature (Fig. 7). The Vickers hardness HV at room temperature was 390 units (Fig. 3).

Embodiment 55:

Alloy 22 with the following composition was melted in an oven in accordance with Example 47:
Ti = 47 at%
Ge = 2 at%
Zr = 3 at .-%
Al = 48 at .-%

The yield point σ _0.2 at room temperature was 513 MPa (Fig. 7). The Vickers hardness HV at room temperature was 311 units (FIG. 3).

Embodiment 56:

Similar to example 47, alloy 23 was melted from the elements:
Ti = 48.5 at .-%
Ge = 0.5 at .-%
Y = 3 at .-%
Al = 48 at .-%

At room temperature the yield point σ _{0.2 was} approx. 539 MPa (Fig. 7). The Vickers hardness HV was 326 units at room temperature (FIG. 3).

Embodiment 57:

According to Example 47, alloy 24 of the following composition was melted from the elements:
Ti = 50.5 at .-%
Ge = 0.5 at .-%
Zr = 1 atom%
Al = 48 at .-%

The yield point σ _0.2 at room temperature reached 416 MPa (Fig. 7). The Vickers hardness HV at room temperature corresponded to 252 units (Fig. 3).

Example 58:

According to Example 47, alloy 25 of the following composition was melted:
Ti = 48.5 at .-%
Ge = 0.5 at .-%
Zr = 3 at .-%
Al = 48 at .-%

At room temperature the yield point σ was _0.2 509 MPa (Fig. 7). The Vickers hardness HV at room temperature reached 308 units (Fig. 3).

Embodiment 59:

Alloy 26 of the following composition was melted from the pure elements in an oven under protective gas:
Ti = 48.5 at .-%
Ge = 0.5 at .-%
Pd = 3 at .-%
Al = 48 at .-%

The yield point σ _0.2 at room temperature was measured at 498 MPa (Fig. 7). The Vickers hardness HV at room temperature gave a value of 302 units (FIG. 3).

Embodiment 60:

According to Example 47, the following alloy 27 was melted under a protective gas:
Ti = 48.5 at .-%
Ge = 0.5 at .-%
Co = 3 at .-%
Al = 48 at .-%

The yield point σ _0.2 at room temperature gave an average value of 488 MPa (Fig. 7). The Vickers hardness HV at room temperature was 296 units (FIG. 3).

Effect of the elements in the exemplary embodiments 34-60:

By adding the elements Y, Zr, Pd, Ge or Co to a Ti / Al base alloy, an increase in hardness and strength is achieved in all cases. The effect is arranged in a descending order: ZY acts the strongest, Co the weakest.

In general, the increase in hardness is associated with a more or less severe loss of ductility, which can, however, be at least partially compensated for by adding further elements which increase the toughness.
The addition of less than 0.5 at.% Of an element is usually hardly effective. On the other hand, there is a certain amount of saturation at about 3 - 4 at%, so that further additions are pointless or the properties of the material as a whole deteriorate again.
B generally has a strong toughness-increasing effect in combination with other strength-increasing elements. See Fig. 10. Here, the loss of ductility caused by alloying Y could be practically compensated for by adding only 0.5 at.% B. Additions higher than 1 at.% B are not necessary. In certain cases, Ge looks similar to B but is considerably weaker. Additions of more than 2 at.% Ge in the presence of further elements are of little use.
For further optimization of the properties, there are polynary systems in which an attempt is made to make up for the negative properties of individual additions by simultaneously alloying other elements.

The area of application of the modified titanium aluminides advantageously extends to temperatures between 600 ° C. and 1000 ° C.

Embodiment 61:

Alloy 33 of the following composition was melted in an arc furnace under argon as protective gas:
Ti = 50.5 at .-%
W = 1 atom%
B = 0.5 at%
Al = 48 at .-%

The individual elements with a purity of 99.99% served as the starting materials. The melt was poured into a cast blank of approximately 60 mm in diameter and approximately 80 mm in height. The blank was melted again under protective gas and also forced under solidification to solidify in the form of rods with a diameter of approximately 12 mm and a length of approximately 80 mm.

The bars were processed directly into pressure samples for short-term tests without subsequent heat treatment.

A further improvement of the mechanical properties through a suitable heat treatment is within the realms of possibility. There is also the possibility of improvement by directional solidification, for which the alloy is particularly suitable.

The Vickers hardness HV (kg / mm²) at room temperature gave a value of 266 units (Fig. 4). Alloys 1 (pure TiAl) and alloy 2 (48 at% Al, remainder Ti) are shown as reference values for this. The yield point σ _0.2 (MPa) at room temperature was 440 MPa (Fig. 8). Alloys 1 (pure TiAl) and alloy 2 (48 at% Al and 52 at% Ti) are again given as reference values for this (FIG. 8).

Example 62:

Analogous to Example 61, the following alloy 34 was melted under argon:
Ti = 48.5 at .-%
W = 3 at%
B = 0.5 at%
Al = 48 at .-%

The melt was poured off analogously to embodiment 61, melted again under argon and forced to solidify in the form of a rod. The dimensions of the rods corresponded to the exemplary embodiment 61. The rods were processed directly into pressure samples without subsequent heat treatment. The values of the mechanical properties achieved as a function of the test temperature are shown in FIGS. 4 and 8. These values can be further improved by heat treatment. The Vickers hardness HV at room temperature was 329 units. The yield point σ _0.2 at room temperature reached 543 MPa. The strength and hardness increasing effect of the W additive is clearly visible.

Example 63:

Exactly the same as in Example 61, the following alloy 35 was melted under an argon atmosphere:
Ti = 48 at%
W = 3 at%
B = 1 atom%
Al = 48 at .-%

The Vickers hardness at room temperature was 342 units (Fig. 4). The yield point σ _0.2 at room temperature was 565 MPa (Fig. 8). The mechanical properties are hardly changed by the further addition of boron up to 1 atom%. Therefore, this value is also a justified upper limit for the boron content of the alloy.

Example 64:

According to Example 61, the following alloy 36 was melted from the pure elements:
Ti = 49.5 at .-%
Mn = 2 at%
B = 0.5 at%
Al = 48 at .-%

At room temperature the Vickers hardness was 295 units (Fig. 4). The yield point σ _0.2 at room temperature was 487 MPa (Fig. 8). The hardness-increasing effect of manganese is therefore somewhat weaker than that of tungsten with the same boron content.

Example 65:

The following alloy 37 was melted according to Example 61:
Ti = 48.5 at .-%
Cr = 3 at .-%
B = 0.5 at%
Al = 48 at .-%

The Vickers hardness at room temperature reached 350 units (Fig. 4). At room temperature the yield point was σ _0.2 578 MPa (Fig. 8). The combined addition of tungsten and boron apparently achieves the highest increase in strength of the series of doped TiAl examined here.

Embodiment 66:

According to Example 61, the following alloy 38 was melted from the pure elements under a protective gas atmosphere:
Ti = 47.5 at .-%
Mn = 2 at%
Nb = 2 at%
B = 0.5 at%
Al = 48 at .-%

At room temperature the Vickers hardness was 323 units (Fig. 4). The yield point σ _0.2 was 533 MPa at room temperature (Fig. 8). The combined effect of manganese and boron with the simultaneous presence of 2 at.% Niobium corresponds approximately to that of chromium with boron.

Embodiment 67:

According to Example 61, the alloy 39 with the following composition was melted:
Ti = 48.5 at .-%
Cr = 2 at .-%
Mn = 1 atom%
B = 0.5 at%
A% = 48 at .-%

The examination showed a Vickers hardness at room temperature of 345 units (FIG. 4). At room temperature, a yield point σ _0.2 of 569 MPa was measured (Fig. 8).

The influence of W and B on the mechanical properties is shown again in FIG. 11. For the other doping elements, similarly shaped curves result. The hardness usually runs through a maximum at about 3 to 4 at.% Doping element. Additions significantly higher than 4 at.% Are therefore not very useful. This applies at least strictly to the individual elements.

Embodiment 68-77:

According to Example 61, the following alloys were melted under an argon atmosphere:
Ti = 48.5 at .-%
Nb = 3 at%
B = 0.5 at%
Al = 48 at .-%
Ti = 46.5 at .-%
W = 3 at%
Cr = 2 at .-%
B = 0.5 at%
Al = 48 at .-%
Ti = 46 at%
W = 1 atom%
Cr = 2 at .-%
Nb = 2 at%
B = 1 atom%
Al = 48 at .-%
Ti = 46.5 at .-%
W = 2 at%
Mn = 1 atom%
Nb = 2 at%
B = 0.5 at%
Al = 48 at .-%
Ti = 46 at%
W = 1 atom%
Cr = 1 atom%
Mn = 2 at%
Nb = 1 atom%
B = 1 atom%
Al = 48 at .-%
Ti = 47 at%
W = 3 at%
Mn = 3 at%
B = 1 atom%
Al = 46 at%
Ti = 47 at%
W = 4 at%
Nb = 1 atom%
B = 0.5 at%
Al = 47.5 at .-%
Ti = 46.5 at .-%
Cr = 2 at .-%
Nb = 1 atom%
B = 0.5 at%
Al = 50 at%
Ti = 46.2 at%
W = 1 atom%
Cr = 1 atom%
Mn = 0.7 at%
B = 0.1 at%
Al = 51 at%
Ti = 46 at%
Cr = 0.7 at%
Mn = 0.6 at.%
Nb = 0.5 at.%
B = 0.2 at%
Al = 52 at%

Otherwise, the procedure was as in Example 61.

Effect of the elements in the exemplary embodiments 61-77:

By adding the elements W, Cr, Mn and Nb individually or in combination to a Ti / Al base alloy, an increase in hardness and strength is achieved in all cases. The effect of combinations (eg Mn + Nb) is strongest. In general, the increase in hardness is associated with a more or less severe loss of ductility, which can, however, be at least partially compensated for by adding further elements which increase the toughness.
The addition of less than 0.5 at.% Of an element is usually hardly effective. On the other hand, there is a certain saturation phenomenon at approx. 3 - 4 at%, so that further additions are pointless or the properties of the material as a whole deteriorate again.

B generally has a strong toughness-increasing effect in combination with other elements that increase strength (FIG. 11). Here the loss of ductility caused by alloying W could be practically compensated for by adding only 0.5 at.% B. Additions higher than 1 at.% B are not necessary.
For further optimization of the properties, there are polynary systems in which an attempt is made to make up for the negative properties of individual additions by simultaneously alloying other elements.

The area of application of the modified tianaluminides advantageously extends to temperatures between 600 ° C. and 1000 ° C.

0,46 ≦ x

≦ 0,54,

0,001 ≦ y

≦ 0,015 für El = Ge und Me = Cr, Hf, Mn, Mo, Nb, Ta, V und/oder W,

0,001 ≦ y

≦ 0,015 für El = Si und Me = Hf, Mn, Mo, Ta, V und/oder W,

0 ≦ y

≦ 0,01 für El = B und Me = Co, Ge, Pd, Y und/oder Zr ,

0 ≦ y

≦ 0,02 für El = Ge und Me = Co, Ge, Pd, Y und/oder Zr,

0,0001 ≦ y

≦ 0,01 für El = B und Me = Cr, Mn, Nb und/oder W,

0,01 ≦ z

≦ 0,04, falls Me = Einzelelement,

0,01 ≦ z

≦ 0,08, falls Me zwei oder mehr Einzelelemente und

0,46 ≦ (x+y+z)

≦ 0,54.

The high-temperature alloy according to the invention for mechanically highly stressed components of thermal machines is not limited to the exemplary embodiments and can have the following composition:



Ti _x El _y Me _z Al _{1- (x + y + z)}

, in which

El = B, Ge or Si and Me = Co, Cr, Ge, Hf, Mn, Mo, Nb, Pd, Ta, V, W, Y, and / or Zr mean and apply:

0.46 ≦ x

≦ 0.54,

0.001 ≦ y

≦ 0.015 for El = Ge and Me = Cr, Hf, Mn, Mo, Nb, Ta, V and / or W,

0.001 ≦ y

≦ 0.015 for El = Si and Me = Hf, Mn, Mo, Ta, V and / or W,

0 ≦ y

≦ 0.01 for El = B and Me = Co, Ge, Pd, Y and / or Zr,

0 ≦ y

≦ 0.02 for El = Ge and Me = Co, Ge, Pd, Y and / or Zr,

0.0001 ≦ y

≦ 0.01 for El = B and Me = Cr, Mn, Nb and / or W,

0.01 ≦ z

≦ 0.04 if Me = single element,

0.01 ≦ z

≦ 0.08 if Me has two or more individual elements and

0.46 ≦ (x + y + z)

≦ 0.54.

Claims (1)

High-temperature alloy for machine components based on doped TiAl with the following composition:



Ti _x El _y Me _z Al _{1- (x + y + z)}

, in which

El = B, Ge or Si and Me = Co, Cr, Ge, Hf, Mn, Mo, Nb, Pd, Ta, V, W, Y, and / or Zr mean and apply: 0.46 ≦ x ≦ 0.54, 0.001 ≦ y ≦ 0.015 for El = Ge and Me = Cr, Hf, Mn, Mo, Nb, Ta, V and / or W, 0.001 ≦ y ≦ 0.015 for El = Si and Me = Hf, Mn, Mo, Ta, V and / or W, 0 ≦ y ≦ 0.01 for El = B and Me = Co, Ge, Pd, Y and / or Zr, 0 ≦ y ≦ 0.02 for El = Ge and Me = Co, Ge, Pd, Y and / or Zr, 0.0001 ≦ y ≦ 0.01 for El = B and Me = Cr, Mn, Nb and / or W, 0.01 ≦ z ≦ 0.04, if Me = single element, 0.01 ≦ z ≦ 0.08 if Me has two or more individual elements and 0.46 ≦ (x + y + z) ≦ 0.54.

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