CN107099698B

CN107099698B - A kind of preparation method of superhigh intensity Ni-Mn-Ga-Hf memorial alloys

Info

Publication number: CN107099698B
Application number: CN201710477767.7A
Authority: CN
Inventors: 董桂馥; 王通; 王兴安; 赵益民
Original assignee: Dalian University
Current assignee: Dalian University
Priority date: 2017-06-20
Filing date: 2017-06-20
Publication date: 2018-06-22
Anticipated expiration: 2037-06-20
Also published as: CN107099698A

Abstract

The present invention relates to a kind of preparation method of New Shape Memory Alloys, particularly a kind of preparation method of superhigh intensity Ni Mn Ga Hf memorial alloys.Marmem Ni prepared by the present invention₅₃Mn₂₅Ga₂₁Hf₁Application extension for high temperature high-ductility marmem thinking.The Ni of the present invention₅₃Mn₂₅Ga₂₁Hf₁It is prepared as follows：According to atomic percent feeding, vacuumize, melting plus Mn elements continue melting, cleaning, keep the temperature, Homogenization Treatments are carried out in water of quenching, by changing aging temp and aging time to get to superhigh intensity Ni₅₃Mn₂₅Ga₂₁Hf₁Alloy.Ni prepared by the present invention₅₃Mn₂₅Ga₂₁Hf₁Alloy has many advantages, such as that good toughness, intensity are big.

Description

A kind of preparation method of superhigh intensity Ni-Mn-Ga-Hf memorial alloys

Technical field

The present invention relates to a kind of high intensity Ni-Mn-Ga-Hf memorial alloy preparation methods.

Background technology

Ni-Mn-Ga marmems are a kind of novel intelligent ferromagnetic shape memory materials, have thermo elastic martensite concurrently Phase transformation and ferromagnetic transition, not only with conventional shape-memory alloy by the shape memory effect of Temperature Field Control, but also can Shape memory effect is generated under magnetic fields.For the response frequency of its magneto-shape-memory effect close to piezoelectric ceramics, output should Become close to traditional temperature control marmem, be a kind of intellectual material of great future in engineering applications.The characteristics of because of its uniqueness It is made also to be able to extensive use in terms of driver and sensor.

But Ni-Mn-Ga block materials still have the shortcomings of brittleness is big, intensity is low and restoring force is small, it significantly limits The engineer application of the material and its development.These become the main bottleneck that magnetic driven memory alloy is applied and developed.So how The intensity of alloy is improved, reduces brittleness, improves alloy mechanical performance, obtains big magnetic entropy change and giant magnetoresistance effect, it has also become note Recall the main direction of studying of Alloyapplication and development.

Invention content

Big in order to solve existing Ni-Mn-Ga alloys brittleness, the shortcomings of intensity is low and restoring force is small, we take timeliness Method increases the intensity of alloy and increases plasticity.It is strong to provide a kind of novel superelevation by changing aging temp and time The Ni of degree₅₃Mn₂₅Ga₂₁Hf₁Memorial alloy preparation method.

The marmem of the present invention is prepared as follows：

(1) 53 parts of Ni, 25 parts of Mn, 21 parts of Ga and 1 part of Hf is taken to be put into vacuum intermediate-frequency induction melting furnace according to atomic percent In, it is sequentially placed raw material in the following order：Hf is placed first, is subsequently placed with Ni, is finally putting into Ga, since the height of Mn elements is waved Mn is placed on spare in material alloying device, close side fire door by hair property, when charging in advance；

(2) before melting, 10 × 10 are evacuated down to^-3-3×10^-3Pa is re-filled with noble gas to 1-0.2Pa, starts melting, control Monitor system is between 350-500Kw.Due to the Principle of Melting of Medium frequency induction itself, the metal liquid after thawing will be in electromagnetism Stirring is flowed under the action of, is eventually adding Mn after the metal liquid being melted is by abundant mixing, by aluminium alloy after 3-5min Body is poured into bar molds, obtains sample, treats that its cooling is taken out；

(3) by sample through wire cutting and mechanical polishing removal surface impurity, it is 10 that vacuum degree is enclosed after cleaning^-1The quartz of Pa Guan Zhong keeps the temperature 5 hours under conditions of 1000 DEG C and carries out Homogenization Treatments；Then by obtained alloy carry out 500-800 DEG C, The ageing treatment of 0.5-5h, you can obtain the Ni of superhigh intensity₅₃Mn₂₅Ga₂₁Hf₁Alloy.

Further, noble gas is high-purity argon gas in the step (2).

Further, acetone washed samples, then vacuum processing are used in the step (3).

Further, described vacuumize using equipment can be mechanical pump or lobe pump.

Another object of the present invention is claimed the above method and prepares superhigh intensity Ni-Mn-Ga-Hf memorial alloys Ni₅₃Mn₂₅Ga₂₁Hf₁。

Alloying can significantly change alloy transformation temperature and improve its mechanical performance and physical property.Inventor by In Ni-Mn-Ga ternary alloy three-partalloys with ion electricity price is higher, radius is smaller, have compared with macroion field strength (ion electricity price and radius it Than) element Hf doping substitute part Ni members usually improve alloy mechanical property do not reduce or slightly reduce alloy martensite phase Phase transition temperature, to provide a kind of novel high intensity Ni-Mn-Ga-Hf memorial alloys.Since Mn element saturated vapour pressures are higher, Volatile, in existing preparation method, the volatile quantity of Mn is difficult to control, can not in exact alloy Mn content, inventor uses Hf is placed first, then puts Ni, is subsequently placed into Ga, is finally putting into the feed way of Mn, and solve that component content accurately controls asks Topic.

The high intensity Ni that inventor is prepared using vacuum intermediate-frequency induction melting furnace₅₃Mn₂₅Ga₂₁Hf₁Alloy, then to it Carry out ageing treatment, find the fracture strength of alloy and breaking strain presented with the increase of aging temp gradually it is increased become Gesture, when aging temp is higher than 600 DEG C, fracture strength presentation is quick increases, up to 7734MPa；Breaking strain is first quick to be increased After be slowly increased, highest breaking strain be 17.8%, this never Leader in NiMnGa alloys is crossed, this can become memory close Gold application and a kind of new material of development.Therefore shape memory aging alloy Ni₅₃Mn₂₅Ga₂₁Hf₁Development will be to material Using and expand open up new thinking.

Vacuum intermediate-frequency induction melting furnace is that eddy heating for heating is generated in metallic conductor using electromagnetic induction under vacuum Furnace charge carries out the method for melting.Small with melting, pumpdown time and melting cycle are short, controlled convenient for temperature, pressure, The features such as being easily recycled Volatile Elements and accurate composition control.

The shape memory metal shape memorial alloy Ni that the method for the present invention is prepared₅₃Mn₂₅Ga₂₁Hf₁Different from using vacuum Ni-Mn-Ga alloys prepared by non-consumable smelting furnace have many advantages, such as that fracture strength is high, toughness is big, and this method is grasped by comparison Make alloy property that is simple, preparing to stablize, new approaches have been expanded in the field for high intensity and high-ductility marmem.

Description of the drawings

Fig. 1 is Ni prepared by the present invention₅₃Mn₂₅Ga₂₁Hf₁The light micrograph of alloy；Wherein (a) figure is alloy in room Light micrograph under temperature, light micrograph of (b) figure alloy after 500 DEG C/3h ageing treatments, (c) figure are alloy warps Light micrograph after 600 DEG C/3h ageing treatments, (d) figure are that optics of the alloy after 700 DEG C/3h ageing treatments is shown Micro- photo, (e) figure are light micrograph of the alloy after 800 DEG C/3h ageing treatments；

Fig. 2 is Ni prepared by the present invention₅₃Mn₂₅Ga₂₁Hf₁The XRD spectrum of alloy；Wherein (a) figure be alloy through 700 DEG C/ Light micrograph after 0.5h ageing treatments, (b) figure are light micrograph of the alloy after 700 DEG C/1h ageing treatments, (c) figure is light micrograph of the alloy after 700 DEG C/3h ageing treatments, and (d) figure is alloy through 700 DEG C/5h ageing treatments Light micrograph afterwards；

Fig. 3 is Ni prepared by the present invention₅₃Mn₂₅Ga₂₁Hf₁Room temperature pressure of the memorial alloy after 800 DEG C/3h ageing treatments Stress under compression and strain curve；

Fig. 4 is Ni prepared by the present invention₅₃Mn₂₅Ga₂₁Hf₁Memorial alloy alloy after different aging temp ageing treatments Fracture strength changes；

Fig. 5 is Ni prepared by the present invention₅₃Mn₂₅Ga₂₁Hf₁Memorial alloy alloy after different aging temp ageing treatments Breaking strain changes；

Fig. 6 is Ni₅₃Mn₂₅Ga₂₁Hf₁The fracture strength of memorial alloy alloy after 700 DEG C of different time ageing treatments；

Fig. 7 is Ni₅₃Mn₂₅Ga₂₁Hf₁The change of memorial alloy breaking strain of alloy after 700 DEG C of different time ageing treatments Change.

Specific embodiment

The present invention is described in further detail, but does not limit the scope of the invention below by embodiment.Such as without spy Different explanation, experimental method of the present invention is conventional method, and experiment equipment used, material, reagent etc. can be chemically Company buys.Vacuum intermediate-frequency induction melting furnace is purchased from Shanghai Twilight electric furnace Co., Ltd.

Embodiment 1

The high intensity Ni of the present embodiment₅₃Mn₂₅Ga₂₁Hf₁The preparation method of memorial alloy is prepared as follows：It presses 53 parts of Ni, 25 parts of Mn, 21 parts Ga and 1 part of rare element Hf is taken to be put into vacuum intermediate-frequency induction melting furnace according to atomic percent, It is sequentially placed raw material in the following order：Rare element Hf is placed first, is subsequently placed with Ni pieces, is finally putting into Ga, and when charging is pre- First Mn is placed on it is spare in material alloying device, after Hf, Ni, Ga melt uniformly after, add Mn.Before melting, using mechanical pump, Lobe pump is evacuated down to 6.67 × 10^-3Pa is re-filled with high-purity argon gas to 0.2Pa.Start melting, control monitor system 500Kw.When The metal liquid being melted is eventually adding Mn pieces after abundant mixing, and 3-5min pours into alloy liquid in bar molds, obtains The bar samples of Φ 12mm × 60mm treat that its cooling is taken out.Test material is used through wire cutting and mechanical polishing removal surface impurity It is 10 that vacuum degree is enclosed after acetone cleaning^-1In the quartz ampoule of Pa, under conditions of 1000 DEG C keeping the temperature 5 hours carries out at homogenization Reason；Obtain Ni₅₃Mn₂₅Ga₂₁Hf₁Marmem.

Embodiment 2

The high intensity Ni of the present embodiment₅₃Mn₂₅Ga₂₁Hf₁The preparation method of memorial alloy is prepared as follows：It presses It is carried out according to aging temp and aging time is changed, specific steps are as follows：Aging time fixed first, respectively heats sample It is strong to get the superelevation handled to different aging times into 500 DEG C, 600 DEG C, 700 DEG C and 800 DEG C heat preservations, 3 hours water of quenching again Spend Ni₅₃Mn₂₅Ga₂₁Hf₁Marmem.

Embodiment 3

Difference lies in 700 DEG C of aging temp changes aging time to the present embodiment under conditions of remaining unchanged with embodiment 1 Respectively 0.5h, 1h, 3h and 5h.It is other same as the specific embodiment one.

Embodiment 4

53 parts of Ni, 25 parts of Mn, 21 parts Ga and 1 part of rare element Hf is taken to be put into vacuum intermediate-frequency sensing according to atomic percent In smelting furnace, rare element Hf being placed first, is subsequently placed with Ni pieces, is finally putting into Ga, Mn is placed on alloy in advance and added by when charging It is spare in material device, after Hf, Ni, Ga melt uniformly, add Mn.Before melting, 10 are evacuated down to using mechanical pump, lobe pump ×10^-3Pa is re-filled with high-purity argon gas to 0.2Pa.Start melting, control monitor system 350Kw.When the metal liquid quilt being melted Mn pieces are eventually adding after abundant mixing, 3-5min pours into alloy liquid in bar molds, obtains the rodlike of Φ 12mm × 60mm Sample treats that its cooling is taken out.Test material encloses vacuum through wire cutting and mechanical polishing removal surface impurity after being cleaned with acetone Spend is 10^-1In the quartz ampoule of Pa, 5 hours are kept the temperature under conditions of 1000 DEG C and carries out Homogenization Treatments；Then the alloy that will be obtained 3h are kept the temperature in 800 DEG C to quench again in water to get to Ni₅₃Mn₂₅Ga₂₁Hf₁Marmem.

Superhigh intensity Ni prepared by embodiment 2 and 3₅₃Mn₂₅Ga₂₁Hf₁Alloy microstructure is analyzed, and Fig. 1 is superhigh intensity The light micrograph that alloy structure changes with aging temp, the precipitated phase in all alloys is at any time as seen in Figure 1 The increase of effect temperature first increases to be reduced afterwards.

Fig. 2 is the light micrograph that changes with aging time of superstrength alloy tissue, as can be seen from Figure 2 with It and phase amount increase is precipitated in the increase alloy of aging time.

Superstrength alloy prepared by the present invention carries out the test of fracture strength and breaking strain, test result such as Fig. 3 Shown, prepared by present invention Ni₅₃Mn₂₅Ga₂₁Hf₁Fracture strength is in 7734Mpa after 800 DEG C/3h ageing treatments for alloy, than not Ni through ageing treatment₅₃Mn₂₅Ga₂₁Hf₁Fracture strength be about 3300MPa.Ni prepared by the present invention₅₃Mn₂₅Ga₂₁Hf₁Alloy breaks Resistance to spalling increases with the increase of aging time, increases 594834MPa from 4684MPa, is improved about than existing Ni-Mn-Ga alloys 4000-5000Mpa。

By Ni obtained in the present embodiment 2-3₅₃Mn₂₅Ga₂₁Hf₁Fracture strength and breaking strain with aging temp and The variation test result of aging time is as shown in Figure 4 and Figure 5；Ni prepared by the present invention₅₃Mn₂₅Ga₂₁Hf₁The highest of alloy is broken Resistance to spalling is 7734MPa, and highest breaking strain is 18%, illustrates Ni prepared by the present invention₅₃Mn₂₅Ga₂₁Hf₁Alloy ductility is big. Ni prepared by the present invention₅₃Mn₂₅Ga₂₁Hf₁Alloy fracture intensity increases with the increase of aging temp, increases to from 4376MPa 7734MPa improves about 3500-7000Mpa than existing Ni-Mn-Ga alloys；Increase to 17.8% from 12.8%, than existing Ni- Mn-Ga alloys improve about 200%-350%；Ni prepared by the present invention₅₃Mn₂₅Ga₂₁Hf₁Alloy fracture is strained with aging time Increase first increases to be reduced afterwards, is increased to 16.7% from 12.8% and is dropped to 14.4, is improved about than existing Ni-Mn-Ga alloys 200%-350%.

Claims

1. a kind of preparation method of superhigh intensity Ni-Mn-Ga-Hf memorial alloys, which is characterized in that include the following steps：

(1) 53 parts of Ni, 25 parts of Mn, 21 parts of Ga and 1 part of Hf is taken to be put into vacuum intermediate-frequency induction melting furnace according to atomic percent, pressed Raw material is sequentially placed according to following sequence：Hf is placed first, is subsequently placed with Ni, is finally putting into Ga, and Mn is placed on conjunction by when charging in advance It is spare in golden feeding device, close side fire door；

(2) before melting, 10 × 10 are evacuated down to^-3-3×10^-3Pa is re-filled with noble gas to 1-0.2Pa, starts melting, control melting Power is in 350-500kW；Mn is eventually adding after metal liquid Ga, Hf, the Ni being melted are by abundant mixing, it will after 3-5min Mixed alloy liquid is poured into bar molds, obtains sample, treats that its cooling is taken out；

(3) by sample through wire cutting and mechanical polishing removal surface impurity, it is 10 that vacuum degree is enclosed after cleaning^-1The quartz ampoule of Pa In, 5 hours are kept the temperature under conditions of 1000 DEG C and carries out Homogenization Treatments；Then obtained alloy is subjected to 500-800 DEG C, 0.5- The ageing treatment of 5h is up to Ni₅₃Mn₂₅Ga₂₁Hf₁Marmem.

2. a kind of preparation method of superhigh intensity Ni-Mn-Ga-Hf memorial alloys according to claim 1, feature exist In noble gas is high-purity argon gas in the step (2).

3. a kind of preparation method of superhigh intensity Ni-Mn-Ga-Hf memorial alloys according to claim 1, feature exist In using acetone washed samples, then vacuum processing in the step (3).

4. a kind of preparation method of superhigh intensity Ni-Mn-Ga-Hf memorial alloys according to claim 1, feature exist In described vacuumize using equipment can be mechanical pump or lobe pump.

5. a kind of method as described in claim 1 prepares superhigh intensity Ni-Mn-Ga-Hf memorial alloys, which is characterized in that the note Alloy is recalled for Ni₅₃Mn₂₅Ga₂₁Hf₁。