DE4318699A1 - Hard-sintered titanium-based alloy - Google Patents

Abstract

A titanium-base sintered alloy comprises a TiC and/or TiN or Ti(C,N) solid solution in an amount of 5 to 70 vol%, with the remainder being composed of two components, the first component being at least one species selected from Groups Va and VIa metallic elements and their mutual solid solutions, and carbides, nitrides, and carbo-nitrides of Groups Va and VIa metallic elements and their mutual solid solutions, and the second component being titanium, with the first component being in an amount of 1 to 30 vol% of the total amount of the first and second components. Preferably the content of TiC or TiN is 35 to 70 vol% and the first component accounts for 1 to 15 vol% of the remainder. It is desirable that the TiC, TiN, and the first component of the remainder be in the form of a solid solution. This alloy exhibits improved wear resistance, strength, and specific strength without any loss in corrosion resistance.

Description

The present invention relates to a hard sintered alloy Titanium-based, suitable as a corrosion and wear solid material for casting molds, pump parts, bearings, mechanical Seals, valves, pipes, tubes, mixers and blades or the same is used.

Conventional corrosion and wear resistant materials for the The above purposes are disclosed by the cemented carbides disclosed in U.S. Pat Unexamined Japanese Patent Publication Nos. 48-17966 and 49-20845, the stellite, the high chromium cast iron and the stainless steel SUS440, disclosed in Japanese Unexamined Patent Publication Nos. 53-125208 and 60-224732, and the Nb alloy and the Ti-6% Al-4% V alloy disclosed in U.S. Pat  Japanese Unexamined Patent Publication No. 4-83837, ver anschaulicht.

Wear resistance and corrosion resistance are together incompatible. Sintered carbide, stellite, cast iron with high chromium content stop and hard stainless steel are in terms of wear strength, but not necessarily good at Corrosion resistance, and thus they can under different Conditions are not used.

In particular, titanium alloys containing 15 to 30 wt .-% molybdenum ent Hold, are known to have a higher corrosion resistance than to have pure titanium. Titanium alloys are regarding the corro superior strength, but in the wear resistance insufficient.

A titanium alloy with improved wear resistance become known which contains a carbide dispersed therein. It is made by melting, as it is in the unaudited Japanese Patent Publication Nos. 2-129330 and 3-285034 is disclosed. Unfortunately, because of the melting, there is Disadvantage. Specifically, it contains carbides in the form of coarse grains ner, resulting in insufficient hardness and wear resistance leads. In addition, it requires difficult machine machining to bring them into pieces of complex shape after casting.

In order to devote to the above-mentioned melting percentage, which coincides with the Titanium alloy, developed the current Inventor one made by powder metallurgy, such as in "Journal of the Japan Society of Powder and Powder Metallurgy ", Vol.22, No. 3. Their development led to a sintered alloy of Ti-30Mo (15.9 vol.% Mo) and  a sintered Ti-Mo-TiC alloy with improved Ver Wear resistance obtained by putting in the former TiC in an amount of 10 to 35% by weight (10.1 to 37.2% by volume) as disclosed in Japanese Patent Publication Nos. 51-19403 and 54-19846.

In the meantime, the most recent chemical and machine require titanium-based sintered alloys, which, under harsher conditions than before, good wear strength as well as show high strength, without any Loss of corrosion resistance inherent in titanium. This need is met by the above-mentioned sintered alloy Ti-Mo-TiC because of their insufficient wear Strength and strength not met. It has, however shown that the sintered alloy Ti-Mo-TiC none exhausts even if the amount of TiC is increased in it.

It is an object of the present invention to provide a sintered Titanium-based alloy to be made available, due to their increased hardness, higher wear resistance and / or Strength and specific strength shows than the conven Liche without any loss of corrosion resistance.

The present invention is in a sintered alloy Titanium based embodies which a solid solution of TiC and / or TiN or Ti (C, N), which is 5 to 70% by volume, the remainder being composed of two components, wherein the first component is at least one substance selected from the group consisting of the metallic elements of groups Va and VIa and their mutual solid solutions and carbides, nitrides and carbonitrides of the metallic elements of Groups Va and  VIa and their mutual solid solutions is selected, wherein the second component is titanium, wherein the first component is 1 to 30 vol .-% of the total amount of first and second component combi matters.

The titanium-based sintered alloy gives a good result when the content of TiC or TiN is 37.2 to 70% by volume, and the first component constitutes 1 to 15% by volume of the remainder.

According to a preferred embodiment, the main inventory which contains TiC and / or TiN or Ti (C, N) in solid solution is, and the first component of the remainder, the at least one Fabric selected from the group consisting of the metallic elements of the groups Va and VIa and their mutual fixed solution and carbides, nitrides and carbonitrides of the metallic Elements of the groups Va and VIa and their mutual solid Solutions is, in the form of a solid solution.

In the following the invention with reference to the accompanying drawings be explained in more detail, in which the only drawing figure a Graphical representation is that shows how the alloy of the before lying invention changes in the bending strength, depending on the amount of TiC, the ratio Mo / (Ti + Mo) remains constant.

The titanium-based hard sintered alloy of the present invention Invention shows high wear resistance and hardness because of their increased content of TiC or TiN, and additionally shows high Strength while the good corrosion resistance because of their Composition M / (Ti + M) in a specific range, where N a metallic element of group Va or VIa or a solid Solution thereof is called, is maintained.  

The following description is made on condition that that the hard sintered titanium-based alloy of Ti, Mo and TiC is composed. This sintered alloy shows two Phases, Ti and TiC, where Mo is more in the Ti phase than in the TiC Phase is solved. The amount of TiC should be carefully controlled because the Ti in the Ti phase dissolves in the TiC phase, which increases the content of Mo in the Ti phase beyond what is intended. The increased Mo content lowers the Bending strength, hardness and corrosion resistance. Around To avoid situation, it is necessary to increase the amount of Mo too reduce if a large amount of TiC in the alloy should be introduced.

According to the present invention, the added metallic Element in the form of a carbide or nitride. In this Case contains the sintered titanium based alloy their metal element in the form of a solid solution in the titanium Phase as well as in the carbide or nitride. The solid solution forms after the carbide or nitride has been decomposed. There this decomposition takes a long time remains the concentration of dissolved substance (metallic element) in the Ti phase low. This favors a precisely controlled Composition with improved physical properties.

Mo, as the dissolved element in the Ti phase, can be partial or completely replaced by Nb, Ta or W belonging to the group Va or VIa belong. Because of their low diffusion coefficients compared with Mo, the concentration of Nb, Ta or W in the Ti phase is less than that of Mo. This bends Grain growth in the TiC or TiN phase before and improves the Hardness and bending strength. The metallic elements in the  Groups Va and VIa have diffusion coefficients in the Ti phase at 1673K as shown below:

Mo 1,158 × 10 ^-12 (m² / s) Nb 0.779 × 10 ^-12 (m² / s) Ta 0.272 × 10 ^-12 (m² / s) W 0.648 × 10 ^-12 (m² / s) V 3.214 × 10 ^-12 (m² / s) Cr 3.899 × 10 ^-12 (m² / s)

Incidentally, although they have larger diffusion coefficients than Mo V and Cr give the sintered alloy a height a degree of hardness and strength when sintering under adequate conditions conditions. In addition, you benefit low specific weight the high specific strength.

The invention will be more clearly understood by reference to following examples; however, these examples only have to Intention to explain the invention should not be used To understand the scope of the invention Zen.

Examples

Commercially available Ti powder, Mo powder and TiC powder were mixed for one hour using an automatic mortar according to the formulation shown in Table 1. The resulting mixture was compression-molded at 2000 kg / cm ² . The compact was sintered at 1300 to 1500 ° C for two hours in a vacuum environment. The resulting sintered body was tested for hardness (H _R C), transverse rupture strength (GPa) and corrosion resistance. The results are shown in Table 2.

(The corrosion resistance is expressed in terms of the rate of corrosion that occurs when the sample is immersed in a dry cell mix for seven days.
○ = 0.05 mm / year or less;
Δ = 0.1 mm / year or less;
X = more than 0.1 mm / year.)

Table 1

Table 2

The following is noted from Tables 1 and 2. The alloys (Samples Nos. 1 to 32) corresponding to the present Invention are in strength and / or hardness and Korro superior strength of the alloy (comparative sample no. 1), that does not contain Mo They are in the strength of the alloy superior (comparative sample # 2) containing a large amount of TiC contains. They are in the wear resistance of the alloys Ti base superior (Comparative Samples Nos. 3 to 5). They are in Hardness and corrosion resistance of the stellite alloy (Comparative Sample No. 6) and SUS304 (Comparative Sample No. 7) think. They are in corrosion resistance to the cemented carbide (Comparative Sample No. 8) far superior.

The above clearly shows that the alloys of the present Invention generally superior to those in the comparative example are.

The drawing figure shows the relationship between hardness (H _R C) and transverse rupture strength (GPa) to the amount of TiC (% by volume) for the alloys listed in Table 1, wherein the ratio of Mo / (Ti + Mo) at 16 vol. -% or 10 vol .-% is held. The ratio of 16% by volume applies to the alloy samples Nos. 26 to 32, and the ratio of 10% by volume applies to the alloy samples Nos. 8, 10, 12, 16, 18, 20 and 22.

It is noted that the hardness reaches its peak when the amount of TiC is around 50 to 55%, with the maximum value for the Mo / (Ti + Mo) ratio of 10% by volume higher than for the Mo / (Ti + Mo) ratio of 16% by volume. It will also noted that the flexural strength decreases as the amount increases with TiC, the values for flexural strength for the Mo / (Ti + Mo) ratio of 10 vol .-% are greater than that for the  Mo / (Ti + Mo) ratio of 16% by volume. This suggests that the Mo / (Ti + Mo) ratio for the high content of TiC be low should, so that the sample obtained a high bending strength becomes. When it comes to corrosion resistance, the samples are with the Mo / (Ti + Mo) ratio of 10% by volume of those with the Mo / (Ti + Mo) ratio of 16 vol% superior. Therefore, that should be Ratio of Mo / (Ti + Mo) preferably in the range of 1 to 15 Vol .-% are, so that the alloys in hardness and bending break strength and corrosion resistance are superior.

The alloy samples Nos. 33 to 55 corresponding to the present Invention were made of Ti and at least one substance made of the metallic elements of the groups Va and VIa and carbides, nitrides and carbonitrides of their mutual solid solutions has been selected. Table 3 shows her Composition and sintering temperature and Table 4 shows their Characteristics such as hardness, bending strength and corrosion resistance and their overall rating.  

Table 4

It is noted that the samples (Nos. 33 to 55) corresponding to the present invention, in hardness, bending strength and corrosion resistance of comparative samples (Nos. 1 to 8) are superior. Sample No. 50 is the most desirable of all.

The samples (Nos. 1 to 3, 33 to 42, 49, 51 and 52), the V, Nb and Ta, other samples (numbers 4 to 32, 43 to 48, 50 and 53 to 55), which did not contain these elements, and the Comparative samples (# 1 to 8) when in a boiling 50% Were immersed in nitric acid mixture.

In addition, the samples (Nos. 1 to 3, 36 to 42, 49, 51 and 52), which contained Nb and Ta, two to five times better than other samples (Nos. 4 to 35, 43 to 48, 50 and 53 to 55), the did not contain these elements, and the comparative samples (# 1 to 8) regarding the oxidation resistance, tested by Heat in the atmosphere at 800 to 900 ° C for a period of time of an hour.

From the foregoing, it is concluded that the alloys, the to the present invention, improved strength and Show wear resistance without loss of corrosion resistance, and that the best result is produced if they are TiC, TiN or Ti (C, N) in an amount of 35 to 70 vol .-% and Mo so contain the ratio of Mo / (Ti + Mo) in the range of 1 to 15% by volume.

According to the present inventions, the following effects shown:

• 1) The alloy shows improved strength, wear strength and specific strength, while those for titanium inherent good corrosion resistance is maintained.
• 2) The alloy composed of Ti (Cr, V) -TiC, is in strength (specific strength) the conven superior Ti-Mo-TiC alloys. She is for korro resistant to wear and tear, the difficult ones Are exposed to conditions.
• 3) The alloy composed of Ti (V, Nb, Ta) -TiC is in terms of corrosion resistance (especially in hot nitric acid) far superior. She becomes her user find use in treatment plants for nuclear fuel.
• 4) The alloy composed of Ti (Nb, Ta) -TiC, is superior in oxidation resistance. she will find their application in power plants where parts are called exposed to corrosive gases.
• 5) The alloy containing TiC, TiN or Ti (C, N) in an amount of Contains 35 to 70 vol .-% and contains Mo, so that the behavior of Mo / (Ti + No) is in the range of 1 to 15 vol.%, is particularly superior in strength, corrosion resistance, Wear resistance. It is more stable than conventional ones Alloys under difficult conditions.
• 6) The alloy is used in corrosion and ver wear-resistant parts as well as forms (to dry cell mixtures pumps, bearings, mechanical seals, venti len, pipes, tubes, mixers and blades or the like in chemical or mechanical industries. Your excellent properties extend the life of the product Parts, reduce the frequency of parts changes and sen ken the required maintenance.  
• 7) The alloy will meet the requirements for use to meet difficult conditions and to improve them operational efficiency.

The in the above description, in the drawing and in The claims disclosed features of the invention can both individually or in any combination for the realization the invention in its various embodiments essential his.

Claims (2)

1. Titanium-based sintered alloy, characterized that they are a solid solution of TiC and / or TiN or Ti (C, N) which is 5 to 70% by volume, with the remainder being two components is composed, with the first compo is at least one substance consisting of the group from metallic elements of groups Va and VIa and their mutual solid solutions and carbides, nitrides and Carbonitrides of metallic elements of groups Va and VIa and their mutual solid solutions is selected and wherein the second component is titanium, wherein the first  Component 1 to 30 vol .-% of the total amount of the first and second component. 2. sintered titanium based alloy according to claim 1, characterized characterized in that the main component, which is TiC and / or TiN or Ti (C, N) in solid solution, and the first component of the remainder, the at least one substance out selects from the group consisting of metallic elements the groups Va and VIa and their mutual fixed solution and carbides, nitrides and carbonitrides of the metal elements of groups Va and VIa and their counterparts solid solutions, in the form of a solid solution available.