JPH03100157A - Production of shape memory alloy - Google Patents

Abstract

PURPOSE:To improve workability and shape memory characteristic in the desired shape by mixing two or more kinds of metal powders in the prescribed ratio, feeding the resulting powder mixture into a plasma spraying device, forming a sprayed deposit on a core mold, and then alloying the above sprayed deposit by means of heat treatment. CONSTITUTION:A plasma spraying device is supplied with a powder mixture prepared by mixing two or more kinds of metal powders consisting of the components of a shape memory alloy in the prescribed ratio, or two or more kinds of metal powders are simultaneously supplied into the plasma spraying device in the prescribed feeding ratio. The above metal powders are plasma- sprayed on the surface of a core mold 3 made of copper, etc., from a powder feeding device 2 by means of a plasma spraying gun 1, by which a sprayed deposit of the desired thickness is formed. The core mold 3 is removed by means, e.g. of dissolution by acid treatment, and the resulting sprayed deposit is subjected to diffusion heat treatment to undergo alloying. Further, when two or more kinds of metal powders are supplied at a feeding ratio changing continuously or in stages, the shape memory alloy dissimilar in transformation temp. in a film forming direction can be produced.

Description

[Detailed description of the invention] [Industrial application field] The present invention relates to a method for manufacturing a shape memory alloy.

[Conventional technology]

Conventionally, shape memory alloys have been manufactured by melting methods, powder metallurgy methods, and the like. By dissolution method, for example, Ti-Ni
When manufacturing practical materials such as alloys, a number of steps have been taken: melting → casting → hot working → cold working → forming and shape memory treatment.

However, Ti-Ni alloys have large work hardening,
Since it has shape memory, it is necessary to perform a large number of intermediate annealings during cold working, making it difficult to form and process a complicated shape. Further, in the case of Cu-Al-Ni type shape memory alloys, there is also a problem of difficulty in hot working and cold working due to coarsening of crystal grains when obtaining an ingot by melting and casting.

On the other hand, the powder metallurgy method does not have the problem of moldability in the above-mentioned melting method, and it is possible to obtain a shape memory alloy having a desired shape. However, it requires complicated processes such as hot isostatic processing (HIP) under ultra-high pressure, and since sintering is performed at high temperatures (approximately 1000°C), the crystal grains become coarse and the mechanical properties deteriorate. There was a problem of deterioration.

As a method for manufacturing a shape memory alloy that solves the above-mentioned problems, a method for manufacturing a shape memory alloy by plasma spraying has been disclosed (Japanese Patent Application Laid-Open No. 140072/1983).

[Problem to be solved by the invention]

However, in the method for manufacturing shape memory alloys by plasma spraying described above, since metal powder that has shape memory properties in the bulk state is used, it is necessary to prepare shape memory alloy powder by manufacturing it in advance according to some manufacturing method. There are problems in that there are many manufacturing steps up to the final product, low work efficiency, and high production costs.

Furthermore, in the above-mentioned melting method, powder metallurgy method, and plasma spraying method for manufacturing shape memory alloys, the component ratio of the shape memory alloy is constant throughout the alloy, and the transformation temperature of the shape memory alloy is almost determined by the component ratio of the alloy. Therefore, it has been almost impossible to manufacture shape memory alloys with continuously or stepwise different transformation temperatures using conventional manufacturing methods.

The present invention was made in order to solve the above-mentioned problems, and it is possible to easily obtain a desired product shape, reduce the manufacturing process and production cost, and have excellent machinability and shape memory properties. The purpose of the present invention is to provide a method for producing an alloy.

Another object of the present invention is to provide a method for manufacturing a shape memory alloy having transformation temperatures that vary continuously or stepwise without increasing the number of work steps.

[Means to solve the problem]

In order to solve this object, the present invention supplies a mixed powder in which two or more kinds of metal powders made of component elements of a shape memory alloy are mixed at a predetermined ratio to a plasma spraying apparatus, or The powders were simultaneously supplied to the plasma spraying apparatus at a predetermined supply ratio to form a sprayed coating on a core having a desired shape, and the sprayed coating was heat-treated to form an alloy.

Further, the two or more types of metal powders are simultaneously supplied to the plasma spraying apparatus at a supply ratio that varies continuously or stepwise to form a sprayed coating on a core having a desired shape,
This thermal spray coating was heat-treated to form an alloy.

[Effect]

A mixed powder prepared in advance by mixing two or more types of metal powders consisting of component elements of a shape memory alloy at a predetermined ratio is supplied to a plasma spraying device, and a sprayed coating is formed on a core having a desired shape. , or the above two or more types of metal powders are simultaneously supplied to a plasma spraying apparatus at a predetermined supply ratio to form a sprayed coating on a core having a desired shape, and the sprayed coating thus formed is composed of the above two types of metal powders. The above metal powders are mixed uniformly, and the film density is almost equal to that of the bulk shape memory alloy obtained by conventional manufacturing methods.
Alloying is achieved by heat-treating this sprayed coating in a vacuum, and a shape memory alloy having a complex shape corresponding to the above-mentioned type 6 is obtained. Further, the two or more types of metal powders are simultaneously supplied to a plasma spraying device at supply ratios that vary continuously or stepwise to form a sprayed coating on a core having a desired shape, and this sprayed coating is heated in a vacuum. Alloying is achieved by heat treatment, and shape memory alloys having transformation temperatures that vary continuously or stepwise in accordance with the above-mentioned supply ratio are obtained.

〔Example〕

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a schematic configuration diagram of a plasma spraying apparatus for explaining the method for manufacturing a shape memory alloy of the present invention. In FIG. 1, a plasma spray gun 1 is for plasma spraying metal powder supplied from a nozzle 2a of a powder supply device 2 onto the surface of a copper tubular core mold 3.

The plasma spray gun 1 and the copper tubular core 3 are placed in a chamber (not shown) in which the atmosphere can be adjusted.The chamber is first evacuated to about 10'TORR, and then argon gas is injected into the chamber. The partial pressure of oxygen is kept low by continuing to pump out air while flowing in. The atmosphere inside the chamber can be, for example, a reduced pressure argon gas atmosphere of about 50 TORR. in this way,
By using argon gas alone without using hydrogen gas, it is possible to prevent hydrogen embrittlement of the Ti powder from occurring when producing the Ti-Ni thread shape memory alloy described below.

The metal powder supplied from the powder supply device 2 is a mixed powder obtained by mixing two or more kinds of metal powders consisting of component elements of the target shape memory alloy at a predetermined ratio. For example, T i
- When manufacturing Ni thread shape memory alloy, Ti powder and N
It is possible to use a mixed powder obtained by accurately weighing the powder and powder i so that the weight ratio becomes 45=55, and then sufficiently stirring and mixing the powder. The particle size of the metal powder used is about 5 to 105 μm, preferably about 10 to 74 μm.

The above metal powder supplied from the powder supply device 2 is plasma sprayed onto the surface of the copper tubular 6 type 3 by the plasma spray gun 1, and the plasma spraying is stopped when a sprayed coating of a desired thickness is formed. .

The copper tubular type 6 type 3 on which the sprayed coating was formed by plasma spraying is dissolved and removed by acid (nitric acid) treatment or cut and removed by machining, and the tubular T i -N i
A mixed spray coating is obtained.

The sprayed coating obtained by such plasma spraying in a reduced pressure atmosphere is a uniform mixture of Ti powder and Ni powder,
Compared to the sprayed coating obtained by plasma spraying performed in the atmosphere, there are extremely few voids, and the coating density is approximately the same density (99% or more) as that of the bulk shape memory alloy obtained by conventional manufacturing methods. Furthermore, since plasma spraying is performed in an argon gas atmosphere, oxidation of Ti powder and Ni powder due to oxygen contamination during spraying is prevented.

The sprayed coating thus obtained is alloyed by diffusion heat treatment. The diffusion heat treatment is performed, for example, by heating and holding the sprayed wave film at 1000° C. for 10 hours under vacuum.

FIG. 2 is a schematic configuration diagram of a plasma spraying apparatus for explaining another embodiment of the present invention. In FIG. 2, a plasma spray gun 11 is for plasma spraying metal powder supplied from a nozzle 12a of a powder supply device 12 and a nozzle 13a of a powder supply device 13 onto the surface of a copper flat plate-shaped 6-type 14. .

Similar to the above-described embodiment, the plasma spray gun 11 and the six flat copper molds 14 are placed in a chamber (not shown) in which the atmosphere can be adjusted.

The two powder supply devices 12 and 13 are, for example, Ti powder.
- When manufacturing a Ni-based shape memory alloy, Ti powder and Ni powder are supplied separately and simultaneously to the plasma spray gun 11. According to the above embodiment, the supply ratio at this time is T
The ratio is such that the weight ratio of i powder to Ni powder is 45:55. In this way, by simultaneously supplying two or more types of metal powders consisting of the component elements of the target shape memory alloy to the plasma spraying apparatus at predetermined supply ratios,
The alloy composition can be easily changed depending on the required transformation temperature of the shape memory alloy. The particle size of the metal powder used is about 5 to 105 μm, preferably 10 to 74 μm.
That's about it.

The sprayed coating thus obtained contains a uniform mixture of Ti powder and Ni powder, has extremely few voids, and has a high coating density, as in the above-mentioned embodiments.

Furthermore, in the present invention, in the plasma spraying apparatus shown in FIG. It can also be changed. FIG. 3 shows T in the plasma spraying apparatus shown in FIG.
It is a figure which shows the flat thermal spray coating 15 formed by continuously changing the supply ratio of i powder and Ni powder so that the amount of Ti powder may increase. The surface 15a of this sprayed wave film 15 is the surface that was in contact with the surface of the copper flat plate type 6 14, and this surface L5a
The sprayed coating 15 has a thickness X in the direction of the opposite surface 15b. Further, FIG. 4 shows Ti-
FIG. 3 is a diagram showing changes in Ni composition. In Figure 4, surface 1
5a, Ti:N1=35:65, and surface 15b
Then, Ti:N1=65:35. -Generally Ti
In the -Ni-based shape memory alloy, the transformation temperature is lowered by about 10° C. by increasing the amount of Ni by 0.1 at %, so the surface 15a of the sprayed coating 15 has a transformation temperature about 300° C. lower than the surface 15b.

In Fig. 4, the supply ratio changes continuously so that the amount of Ti increases, but the amount of Ti may also be increased stepwise, or the amount of Ti is maximum at approximately the center of the thickness X. There is no particular restriction on the change in the supply ratio.

As described above, in the present invention, it is possible to easily produce a shape memory alloy having different transformation temperatures in the thermal spray coating direction.

In each of the above embodiments, the Ti-Ni shape memory alloy was used as an example, but the present invention can be similarly carried out with other two-component shape memory alloys, or multi-component shape memory alloys with three or more components. can do.

〔Effect of the invention〕

As is clear from the detailed description above, according to the present invention, a shape memory alloy is manufactured by plasma spraying using metal powder consisting of constituent elements of a shape memory alloy, thereby reducing production costs and simplifying the manufacturing process. Simplification is possible, and the resulting shape memory alloy can be made into a desired shape, and it is also possible to manufacture shape memory alloys with different transformation temperatures continuously or stepwise without increasing the number of work steps. becomes.

[Brief explanation of drawings]

FIG. 1 is a schematic configuration diagram of a plasma spraying apparatus for explaining the method for manufacturing a shape memory alloy of the present invention, FIG. 2 is a schematic configuration diagram of a plasma spraying apparatus for explaining another embodiment of the present invention, Figure 3 is a diagram showing a flat thermal sprayed coating formed by continuously changing the supply ratio of Ti powder and Ni powder so that the amount of Ti powder increases in the plasma spraying apparatus shown in Figure 2; FIG. 4 is a diagram showing changes in the Ti--Ni composition in the thickness direction of the flat plate-shaped sprayed coating shown in FIG. 3. 1.11...Plasma spray gun, 2.12゜13...
・Powder supply device, 2 a, 12 a, 13 a
...Nozzle, 3.14...6 type, 15...Thermal spray coating.

Claims (2)

[Claims] 1. The plasma spraying is performed by supplying a mixed powder in which two or more types of metal powders consisting of component elements of the shape memory alloy are mixed at a predetermined ratio to a plasma spraying device, or by simultaneously supplying the two or more metal powders at a predetermined supply ratio. 1. A method for producing a shape memory alloy, which comprises supplying a shape memory alloy to an apparatus to form a thermally sprayed coating on a core having a desired shape, and heat-treating the thermally sprayed coating to form an alloy. 2. 2. The method for manufacturing a shape memory alloy according to claim 1, wherein the two or more metal powders are simultaneously supplied to the plasma spraying apparatus at a supply ratio that varies continuously or stepwise.